KR102639705B1 - Buoy for Solar power - Google Patents

Abstract

The present invention relates to a buoy for solar power generation, and in particular, a buoy for solar power generation assembled with a solar power generation facility for solar power generation on the water, comprising a buoy body and a buoy coupled to the buoy body to generate solar power. It includes a cartridge on which the power generation equipment is assembled, wherein the cartridge is removable from the buoy body, so that the solar power generation equipment can be simply and easily assembled into the cartridge that is detachably coupled to the buoy body, cartridge It is designed to be detachable from the buoy body, making recycling and maintenance of the cartridge very easy, and relates to a buoy for solar power generation in which only the cartridge can be replaced without the need to replace the buoy body even if the cartridge is damaged.

Description

Buoy for Solar power}

The present invention relates to a buoy for solar power generation, and more specifically, a solar power generation facility can be simply and easily assembled on a cartridge that is detachably coupled to the buoy body, and the cartridge is configured to be detachable from the buoy body. This relates to a buoy for solar power generation in which the recycling and maintenance of the cartridge are very easy, and even if the cartridge is damaged, only the cartridge can be replaced without the need to replace the buoy body.

While environmental pollution is becoming a major issue around the world, discussions on global warming, among other environmental pollution issues, are actively taking place internationally. Such global warming is intensifying due to various factors, and power generation to provide electricity, which is widely used in various industries and daily life, especially thermal power generation, which generates electricity through combustion of fossil fuels, is contributing to global warming. It is considered a major cause of occurrence. Thermal power generation is a direct cause of global warming because large amounts of carbon dioxide are generated when fossil fuels are burned.

Accordingly, in recent years, various forms of eco-friendly power generation have been proposed to replace thermal power generation, which accelerates global warming, and solar power generation using sunlight as an energy source has been greatly highlighted as one of these forms of power generation.

Solar power generation refers to a power generation method that converts light from the sun into electrical energy using the photovoltaic effect. Solar power generation can be achieved through solar power generation facilities that include solar panels (solar cells), frames, etc. These solar power generation facilities do not require separate maintenance, so solar power can be generated without environmental pollution with just one installation. Electrical energy can be produced by absorbing the light energy and converting it into electrical energy.

Since solar power generation requires a small amount of solar energy received per unit area, a large installation area of solar power generation facilities is required to produce large amounts of electrical energy. For this reason, in the case of urban areas where land is expensive, due to economic constraints, solar power generation facilities are installed only on a small scale on the rooftops of buildings or homes, causing the problem that they only produce supplementary electricity.

To solve this problem, plans have recently been considered to install large-scale solar power generation facilities on shared water surfaces such as the sea, lakes, and reservoirs (hereinafter referred to as water). In this way, when solar power generation equipment is installed on the water, the solar power generation equipment can be installed on the water by being combined and mounted on a plurality of buoys that are typically provided to float on the water.

Regarding such a conventional buoy for solar power generation, there is one published in the Republic of Korea Registered Utility Model Publication No. 20-0493702.

The conventional buoy for solar power generation is entirely surrounded by an outer skin and has a hollow part provided inside, the lower part is open to form a lower opening, and the upper surface of the outer skin has an upper part where a coupling part for coupling the structural frame is formed. half body; and a lower half body that is entirely surrounded by an outer skin and has a hollow portion on the inside, but the upper part is open to form an upper opening portion; wherein the outer skins of the upper and lower half bodies have a streamlined side horizontal and vertical cross section. It is formed to have, the bottom of the outer skin of the upper half body and the top of the outer skin of the lower half body are joined by heat fusion, and the fusion line formed by heat fusion is formed above the height center of the combined buoyancy body, and the upper and lower halves The outermost protrusion in the vertical cross-section of the side of the outer skin is formed lower than the fusion line and is formed on the side of the lower half, and includes at least one vertical plate protruding downward from the bottom of the outer skin of the lower half. It is composed by:

However, in these conventional solar power generation buoys, since the coupling part for joining the structural frame of the solar power generation facility is formed integrally with the upper surface of the outer skin of the upper half, it is impossible to recycle only the coupling part, and at the same time, when the coupling part is damaged, There is a problem that the buoy itself needs to be replaced.

In addition, the conventional buoy for solar power generation has the problem that maintenance of the coupling part is very inconvenient because the coupling part for coupling the structural frame of the solar power generation facility is formed inseparably on the upper surface of the outer skin of the upper half. .

In addition, in the conventional solar power generation buoy, the coupling portion for coupling the structural frame of the solar power generation facility is formed in a form that protrudes upward from the upper surface of the outer skin of the upper half, so waste floating on the water (e.g. There is a problem that damage to the joint may frequently occur due to collision with wood, bottles, etc.) or other external forces.

In addition, the conventional buoy for solar power generation cannot respond to the tolerances of the buoy or structural frame because the coupling part for combining the structural frame of the solar power generation facility is formed integrally with the upper surface of the outer skin of the upper half. There is a problem that it is impossible to adjust the joint position of the structural frame.

In addition, in the conventional buoy for solar power generation, the bottom of the outer skin of the upper half and the top of the outer skin of the lower half are joined by heat fusion, so the heat fusion area may open or fusion failure may occur, causing water to seep into the buoy and reduce buoyancy. Problems with loss may arise.

In addition, when a conventional buoy for solar power generation needs to apply a filler that matches the shape of the internal space, the upper half body and the lower half body are pressed in a direction facing each other in order to firmly adhere the filler to the inner surface of the buoy. There is a problem that separate pressurization equipment is required.

In addition, the conventional buoy for solar power generation has a problem in that it is difficult to selectively apply the upper half body of various shapes as needed.

In addition, conventional buoys for solar power generation have the problem that it is very difficult to stably load, store, or transport multiple buoys.

In addition, the conventional buoy for solar power generation has a problem in that the loading and unloading work of the buoy is carried out in the form of workers lifting and transporting each buoy by hand, which increases the labor load of the worker.

In addition, conventional buoys for solar power generation have a problem in that visibility at long distances or at night is very poor.

KR 20-0493702 Y1

The present invention was devised to solve the above-mentioned problem, and it is possible to simply and easily assemble a solar power generation facility on a cartridge that is detachably coupled to the buoy body, and the cartridge is configured to be detachable from the buoy body so that the cartridge is detachable from the buoy body. The purpose is to provide a buoy for solar power generation that is very easy to recycle and maintain, and where only the cartridge can be replaced without the need to replace the buoy body even if the cartridge is damaged.

The buoy for solar power generation of the present invention to solve the above problems is a buoy for solar power generation that is assembled with solar power generation equipment for solar power generation on the water, and is coupled to a buoy body and the buoy body. It includes a cartridge on which the solar power generation facility is assembled, and the cartridge is characterized in that it is removable from the buoy body.

In addition, a slot is formed in the buoy body, and the cartridge is inserted and mounted in the slot.

In addition, the slot is formed on an upper portion of at least one side of the buoy body, and the cartridge is inserted into the slot in a horizontal direction.

In addition, the cartridge includes a cartridge body having a receiving hole penetrating in an upward and downward direction, and an assembly nut that is accommodated in the receiving hole and is non-rotatably restrained and inserted into the slot together with the cartridge body. do.

In addition, an assembly hole communicating with the slot is formed on the upper surface of the buoy body, and the assembly hole communicates with the receiving hole when the cartridge body is inserted into the slot. The solar power generation facility is, It is characterized in that it is assembled with the assembly nut through the assembly hole.

In addition, the receiving hole includes a first hole that communicates with the lower end of the assembly hole and is formed in the form of a long hole having a first long axis, and a long hole that extends outward along the lower end of the first hole and has a second long axis. and a second hole, wherein the assembly nut includes a nut portion accommodated in the first hole and adjustable in the direction of the first major axis, and expanded outward along a lower end of the nut portion and accommodated in the second hole. It is characterized in that it includes a flange portion that is adjustable in the direction of the second major axis.

In addition, the length of the first long axis is formed to be longer than the outer diameter of the nut part, and the length of the second long axis is formed to be longer than the length of the flange part along the second long axis direction.

In addition, the height of the second hole is formed to be longer than the thickness of the flange portion, and the flange portion rises along the second hole when fastened between the assembly nut and the solar power plant and hangs on the inner upper surface of the second hole. It is characterized by

In addition, a locking hole communicating with the slot is formed on the upper surface of the buoy body, and the cartridge body includes an elastic piece that is elastically deformable, and the elastic piece is engaged or released from the locking hole to It is characterized in that a button portion is formed to enable attachment and detachment of the cartridge.

Additionally, a plate-shaped guide portion is formed in the slot, and a guide slit through which the guide portion is inserted is formed in the cartridge.

In addition, the buoy body includes a first body portion having a first inner space in which an open surface is formed, a second body portion having a second inner space in which an open surface is formed, and an open surface side edge of the first body portion. A double injection is formed by double injection in a form that surrounds the open surface side border of the first body part and the open surface side border of the second body part by an injection molding machine so that the open surface side border of the second body part is joined in a contact state. It is characterized by including wealth.

In addition, before forming the double injection part, a filler is inserted into the first internal space and the second internal space, and when forming the double injection part, the filler is inserted into the first internal space and the second internal space by the pressure of the injection molding machine. It is characterized in that it is in close contact with the inner surface of the second internal space.

In addition, the filler includes a filler body in which a space is opened on one side, and a filler cover that covers the open side of the filler body, wherein the filler body and the filler cover are connected to each other by the pressure of the injection molding machine. It is characterized by being closely adhered and sealed.

In addition, at least one of the first body part and the second body part is characterized in that a plurality of different shapes are provided and can be selectively changed and applied.

In addition, the double injection unit is characterized in that it is formed in a different color from the buoy body.

In addition, the double injection unit is characterized in that a luminescent pigment is applied.

In addition, a receiving portion is formed on the lower surface of the buoy body in a concave shape that intersects the longitudinal direction of the buoy body, and a pair of the receiving portions is formed parallel to each other.

In addition, a plurality of depressions concave downward are formed on the upper surface of the buoy body, and a plurality of protrusions protruding downward are formed on the lower surface of the buoy body.

In addition, the buoy body is characterized in that a plurality of protrusions formed on the other buoy body are seated in the plurality of depressions formed on one of the buoy bodies.

The buoy for solar power generation according to the present invention has the following advantages.

The buoy for solar power generation according to the present invention has the advantage that solar power generation equipment can be simply and easily assembled into a cartridge that is detachably coupled to the buoy body.

In the solar power generation buoy according to the present invention, the cartridge on which the solar power generation equipment is assembled by being coupled to the buoy body is configured to be detachable from the buoy body, so recycling and maintenance of the cartridge is very easy, and even if the cartridge is damaged, It has the advantage of being able to replace only the cartridge without having to replace the buoy body.

In the solar power generation buoy according to the present invention, the cartridge for combining solar power generation equipment is inserted and mounted in the slot of the buoy body without any protruding portion from the buoy body, so it is resistant to collision with waste floating on the water or other external forces. The advantage is that there is no risk of the cartridge being damaged.

The buoy for solar power generation according to the present invention is assembled in the direction of the first major axis and the second major axis of the first hole and the second hole because the assembly nut is accommodated in the receiving hole including the first hole and the second hole in the form of a long hole. The nut is given a degree of freedom, which allows it to respond to the tolerances of the buoy or solar power generation equipment, and has the advantage of being able to finely adjust the coupling position of the solar power generation equipment to the solar power generation buoy.

In the solar power generation buoy according to the present invention, the open surface (bottom) edge of the first body portion and the open surface (top) edge of the second body portion are fixed and joined to each other with a double injection part through double injection, so that the joint area is not opened. It has the advantage of being able to prevent water from seeping into the buoy body and solving the problem of loss of buoyancy.

The buoy for solar power generation according to the present invention, when applying a filler that matches the shape of the internal space, is applied to the inner surface of the buoy body by using the very large pressure of an injection molding machine for manufacturing the buoy body without separate pressurizing equipment. It has the advantage of being able to firmly adhere the filler.

The buoy for solar power generation according to the present invention consists of one of the first body part and the second body part with selection parts of various shapes, the other one of the first body part and the second body part, the double injection part, and By composing the cartridge with common parts, the selected parts can be selectively changed and combined with the common parts as needed, which has the advantage of producing products with various buoyancy at a low investment cost.

The buoy for solar power generation according to the present invention has the advantage that a number of buoys can be stacked, stored, or transported in a stable manner in which depressions and protrusions are formed in the buoy body and the protrusions are seated in the depressions.

The buoy for solar power generation according to the present invention is formed on the lower surface of the buoy body by inserting the fork part of a forklift or handcar to support the lower part of the buoy body, so that mechanized loading and unloading work is possible, thereby reducing the labor of workers. The advantage is that the load can be reduced and work efficiency can be increased.

The buoy for solar power generation according to the present invention can improve visibility by applying different colors to the double injection portion than the first body portion and the second body portion.

The buoy for solar power generation according to the present invention has the advantage of being able to improve visibility, especially at a distance or at night, by applying a luminescent pigment to the double injection part.

Figure 1 is a perspective view showing a buoy for solar power generation according to an embodiment of the present invention.
Figure 2 is a bottom perspective view of Figure 1.
Figure 3 is an exploded perspective view showing the cartridge in Figure 1 disassembled.
Figures 4 (a) and (b) are a top view and a bottom view showing the front cartridge of a buoy for solar power generation according to an embodiment of the present invention.
Figure 5 is a cross-sectional view taken along portion AA of Figure 1.
Figure 6 is a cross-sectional view showing a state in which the solar power generation equipment is assembled to the assembly nut in Figure 5.
Figure 7 is an exploded perspective view showing the buoy body and filler of a buoy for solar power generation according to an embodiment of the present invention.
Figure 8 is an exploded perspective view showing a filler of a different type from the filler in Figure 7.
Figures 9 (a) to (c) are perspective views showing various embodiments other than the first body portion according to an embodiment of the present invention.
Figure 10 is a perspective view showing a stacked state of buoys for solar power generation according to an embodiment of the present invention.

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

For reference, among the configurations of the present invention to be described below, for configurations that are the same as the prior art, the above-described prior art will be referred to and a separate detailed description will be omitted.

The terminology used herein is only intended to refer to specific embodiments and is not intended to limit the invention. As used herein, singular forms also include plural forms unless phrases clearly indicate the contrary. As used in the specification, the meaning of "comprising" is to specify a specific characteristic, area, integer, step, operation, element and/or component, and to specify another specific property, area, integer, step, operation, element, component and/or group. It does not exclude the existence or addition of .

When a component is said to be “connected” or “connected” to another component, it is understood that it may be directly connected or connected to the other component, but that other components may exist in between. It should be.

In addition, in all descriptions below, the front, rear, left, right, top and bottom directions are based on the direction charts shown in FIGS. 1 and 2.

Figure 1 is a perspective view showing a buoy for solar power generation according to an embodiment of the present invention. Figure 2 is a bottom perspective view of Figure 1. Figure 3 is an exploded perspective view showing the cartridge in Figure 1 disassembled. Figures 4 (a) and (b) are a top view and a bottom view showing the front cartridge of a buoy for solar power generation according to an embodiment of the present invention. FIG. 5 is a cross-sectional view taken along portion A-A of FIG. 1. FIG. 6 is a cross-sectional view showing a state in which the solar power generation equipment is assembled to the assembly nut in FIG. 5. Figure 7 is an exploded perspective view showing the buoy body and filler of a buoy for solar power generation according to an embodiment of the present invention.

As shown in FIGS. 1 to 7, the buoy 10 for solar power generation according to an embodiment of the present invention may be formed as a whole into a square box type. The buoy 10 for solar power generation can be floating on water such as the sea, reservoir, or lake for solar power generation on water. The buoy 10 for solar power generation can be assembled with a solar power generation facility (B, see FIG. 6). The solar power generation facility (B) includes a solar panel (solar cell), a frame coupled to the solar power generation buoy (10) so that the solar panel can be supported on the solar power generation buoy (10), and , may include fastening members (for example, bolts) for coupling the frame and the solar power generation buoy 10, but in FIG. 6, only the bolt shape is schematically shown.

Referring to FIGS. 1 to 7 , the buoy 10 for solar power generation may include a buoy body 100. The buoy body 100 may have the appearance of a buoy 10 for solar power generation. As described above, the buoy body 100 may be formed as a whole into a substantially square box type. The buoy body 100 may form internal spaces 110a and 110b therein. The buoy body 100 may be formed to be long in the front-back direction. For example, the buoy body 100 may be formed to have a front-to-back width longer than a left-right width. The buoy body 100 may be manufactured by injection molding from polyethylene (PE, Polyethylene) or polypropylene (PP, Polypropylene).

The buoy body 100 may include a first body portion 110. The first body portion 110 may form the upper part of the buoy body 100. The first body portion 110 may be formed to be long in the front-to-back direction so that the front-to-back width is longer than the left-to-right width. The first body portion 110 may have a first internal space 110a in which an open surface is formed. The open surface of the first internal space 110a may be formed on the lower surface of the first body portion 110.

A depression 111 may be formed in the buoy body 100. The recessed portion 111 may be formed on the upper surface of the first body portion 110. The recessed portion 111 may be concave downward with respect to the upper surface of the first body portion 110 and may have a depressed shape. A plurality of depressions 111 may be provided. For example, the depressions 111 are one each on the front left corner, front right corner, rear left corner, rear right corner, center left, and center right on the upper surface of the first body portion 110. A total of six can be formed and provided. The plurality of depressions 111 may be arranged in two rows along the front-back direction. The depression 111 may be formed to stack a plurality of buoy bodies 100 in the vertical direction along with the protrusion 121.

A slot 113 may be formed in the buoy body 100. The slot 113 may be a space for mounting the cartridge 200 on the buoy body 100. Slot 113 may be formed on at least one side of the buoy body 100. For example, a total of two slots 113 may be formed with one side open, one each on the upper front side and the upper rear side of the first body portion 110. The front slot 113, which is a slot 113 formed on the upper front side of the first body portion 110, may be formed in the form of a square hole with an open front surface. The rear slot 113, which is a slot 113 formed on the upper rear side of the first body portion 110, may be formed in the shape of a square hole with an open rear side. The slot 113 may be a hole having an inverted trapezoidal longitudinal cross-sectional shape. The vertical height of the slot 113 may be shorter than the length of the slot 113 in the front-to-back direction. The length of the slot 113 in the front-to-back direction may be shorter than the length of the slot 113 in the left-right direction. The front slot 113 and the rear slot 113 may have the same shape and be symmetrically positioned forward and backward.

A guide portion 115 may be formed in the slot 113. The guide portion 115 may be formed to correspond to the guide slit 215 of the cartridge 200 mounted in the slot 113. The guide portion 115 may be formed inside the slot 113. The guide portion 115 may be formed in a wide plate shape in the vertical direction. The guide unit 115 may have a vertically standing shape. The guide portion 115 may be formed integrally with the inner upper surface, the inner lower surface, and the surface connecting the inner upper surface and the inner lower surface of the slot 113. Two guide parts 115 may be provided. The two guide parts 115 may be spaced apart in the left and right directions. The guide portion 115 serves to more accurately guide the forward-backward sliding of the cartridge 200 being inserted or withdrawn into the slot 113, and at the same time, the first body portion ( 110) can serve as a rib to reinforce the strength of the upper side.

A locking hole 117 may be formed in the buoy body 100. The catching hole 117 may be formed at the front center of the upper surface and the rear center of the upper surface of the buoy body 100, respectively. The catching hole 117 may be located at the top of the slot 113. The catching hole 117 may be formed in the form of a triangular hole penetrating the upper surface of the first body 110 in the vertical direction. The catching hole 117 may communicate with the slot 113 located below. The button portion 213 of the cartridge 200 is engaged with the locking hole 117 so that the cartridge 200 can be mounted in the slot 113.

An assembly hole 119 may be formed in the buoy body 100. A pair of assembly holes 119 may be formed on the upper front side and upper rear side of the buoy body 100, respectively. For example, a pair of assembly holes 119 may be formed to be spaced apart from each other with a locking hole 117 in between. The pair of assembly holes 119 may be positioned symmetrically with respect to the locking hole 117. The assembly hole 119 may be formed in the form of a long hole similar to an oval that penetrates the upper surface of the first body portion 110 in the vertical direction. The assembly hole 119 may communicate with the slot 113 located below. When the cartridge 200 is mounted in the slot 113, the assembly hole 119 may communicate with the receiving hole 217 formed in the cartridge 200. The assembly hole 119 may serve as an entrance that allows the solar power generation facility (B) to be coupled to the cartridge 200 coupled to the buoy body 100.

The buoy body 100 may include a second body portion 120. The second body portion 120 may form the lower part of the buoy body 100. The second body portion 120 may be formed to be long in the front-to-back direction so that the front-to-back width is longer than the left-to-right width. The second body portion 120 may have a second internal space 120a in which an open surface is formed. The open surface of the second internal space 120a may be formed on the upper surface of the second body portion 120.

A protrusion 121 may be formed on the buoy body 100. The protrusion 121 may be formed on the lower surface of the second body portion 120. The protrusion 121 may be formed to protrude downward with respect to the lower surface of the second body portion 120. A plurality of protrusions 121 may be provided corresponding to the recessed portions 111 formed on the upper surface of the first body portion 110. For example, the protrusions 121 are formed one each on the front left corner, front right corner, rear left corner, rear right corner, center left, and center right on the lower surface of the second body portion 120. A total of six can be provided. The plurality of protrusions 121 may be arranged in two rows along the front-back direction. The protrusion 121 may be formed to stack a plurality of buoy bodies 100 in the vertical direction along with the depression 111.

A receiving portion 123 may be formed in the buoy body 100. The receiving portion 123 may be formed on the lower surface of the second body portion 120. The receiving portion 123 may be formed in a concave shape upward with respect to the lower surface of the second body portion 120. The receiving portion 123 may be formed to extend long from the left side to the right side of the second body portion 120. The receiving portion 123 may be formed to be long in the left and right directions. The receiving portion 123 may be formed so that its lower left and right sides are open. The receiving portion 123 may be formed in a shape that intersects the longitudinal direction of the buoy body 100. A plurality of receiving portions 123 may be provided. For example, two receiving portions 123 may be provided to be spaced apart from each other to form a pair. A pair of receiving portions 123 may be formed parallel to each other so that a pair of fork portions provided in a typical forklift or handcar can be inserted. The receiving portion 123 is between the two protrusions 121 formed on the front left and right corners of the second body portion 120 and the two protrusions 121 formed on the left and right sides of the center of the second body portion 120 and the second One may be formed between the two protrusions 121 formed on the rear left and right corners of the body 120 and the two protrusions 121 formed on the left and right sides of the center of the second body 120. A pair of fork parts provided in a forklift or handcar are inserted into a pair of receiving parts 123 from left to right or right to left and support the inner upper surface of the receiving parts 123, thereby supporting the buoy body 100. The lower part can be lifted. Through this, the buoy 10 for solar power generation can perform mechanized loading and unloading work, thereby reducing the labor load of workers and increasing work efficiency.

The buoy body 100 may include a double injection unit 130. The double injection unit 130 is formed by an injection molding machine so that the open surface side edge of the first body part 110 and the open surface side edge of the second body part 120 are joined in contact with each other. It may be formed by double injection in a form that surrounds the open surface side edge of the second body portion 120 and the open surface side edge of the second body portion 120. The double injection unit 130 may have a belt shape surrounding the entire circumference of the open surface side edge of the first body part 110 and the open surface side edge of the second body part 120 that are in contact with each other. The double injection portion 130 includes a plurality of penetrations formed to oppose the open surface side edge of the first body portion 110 and the open surface side edge of the second body portion 120, respectively, during double injection through an injection molding machine. By being double-injected while being injected into holes (not shown), the open surface side edge of the first body portion 110 and the open surface side edge of the second body portion 120 can be bonded and fixed to each other in a form of weaving. In the solar power generation buoy 10, the open surface side edge of the first body portion 110 and the open surface side edge of the second body portion 120 are fixed and joined to each other through the double injection portion 130. , It is possible to prevent the joint area from opening, and water seeps into the inside of the buoy body 100 between the open surface side edge of the first body portion 110 and the open surface side edge of the second body portion 120 to increase buoyancy. The problem of loss can be solved.

The double injection unit 130 may be formed in a different color from the buoy body 100. The double injection unit 130 may be applied in different colors to the buoy body 100 to improve visibility of the waterline or safe diving depth of the solar power buoy 10. Additionally, a phosphorescent pigment may be applied to the double injection unit 130. The phosphorescent pigment can be provided to the outer peripheral surface of the double injection unit 130 in various ways. For example, the phosphorescent pigment may be applied to the double injection unit 130 in the form of painting, coating, adhesion, etc., over the entire circumference of the outer peripheral surface of the double injection unit 130. The phosphorescent pigment applied to the double injection unit 130 absorbs sunlight during the day and emits the absorbed sunlight when it becomes dark at night, thereby improving the visibility of the waterline or safe diving depth of the solar power generation buoy 10. can be maximized.

1 to 6, the buoy 10 for solar power generation may include a cartridge 200. The cartridge 200 may be configured to fix the solar power generation facility (B) to the buoy 10 for solar power generation. The cartridge 200 is coupled to the buoy body 100 so that the solar power generation facility (B) can be assembled. Cartridge 200 may be detachable from the buoy body 100. The cartridge 200 may be mounted by being inserted into each of the slots 113 formed at the front and rear of the first body portion 110 of the buoy body 100 in the horizontal direction.

Hereinafter, the description will be based on the cartridge 200 being attached to and detached from the slot 113 formed in the front of the first body portion 110.

Cartridge 200 may include a cartridge body 210. The cartridge body 210 may be formed as a hexahedron having an inverted trapezoidal longitudinal cross-sectional shape. The cartridge body 210 may be formed in a shape corresponding to the shape of the slot 113 so that it can be aligned with the slot 113. The cartridge body 210 may be inserted into the first body portion 110 by sliding into the inside of the slot 113, and may be pulled out from the first body portion 110 by sliding from the inside of the slot 113. You can. That is, the cartridge body 210 may be attached to or detached from the slot 113, thereby being detachable from the first body 110 of the buoy body 100.

The cartridge body 210 may include an elastic piece 211. The elastic piece 211 may be formed at the center of the upper surface of the cartridge body 210. The elastic piece 211 is in the form of a cantilever whose front end is integrally fixed to the upper surface of the cartridge body 210, and whose circumference excluding the front end is surrounded by a cutout portion 211a formed through the upper surface of the cartridge body 210. It can be formed as The elastic piece 211 may be elastically deformable in the vertical direction while the shear is fixed. The elastic piece 211 may have a shape in which a triangular piece is integrated at the rear end of a rectangular piece that is formed long in the front-back direction. The elastic piece 211 may have a sharp rear end.

A button portion 213 may be formed on the elastic piece 211. The button portion 213 may be formed on the upper surface of the elastic piece 211. For example, the button portion 213 may be formed to protrude upward to have a triangular shape on the upper surface of the triangular piece of the elastic piece 211. The button portion 213 may be provided in a shape corresponding to the locking hole 117 formed in the first body portion 110 when viewed from a plan view. The protrusion height of the button portion 213 may decrease from the front to the rear. For example, the upper surface of the button portion 213 may be formed with an inclined surface that becomes lower from the front to the rear. The button portion 213 may be locked or released from the locking hole 117 to enable attachment or detachment of the cartridge 200. For example, when the cartridge body 210 is completely inserted into the slot 113, the button portion 213 is received in the catching hole 117 through elastic deformation of the elastic piece 211 and forms the locking hole 117. It can be joined to the inner circumferential surface of the. In addition, when the upper surface of the button portion 213 is pressed with a finger or a separate tool, the button portion 213 is separated from the locking hole 117 through elastic deformation toward the lower side of the elastic piece 211, thereby damaging the inside of the locking hole 117. It can be unlocked from the circumferential surface, and in this state, the cartridge body 210 can be pulled toward the front to remove the cartridge body 210 from the first body portion 110. In this way, the buoy 10 for solar power generation secures the cartridge body 210 to the buoy body 100 through a very simple structure such as engaging or releasing the button portion 213 with respect to the engaging hole 117. It can be mounted properly or removed from the buoy body 100.

A guide slit 215 may be formed in the cartridge body 210. The guide slit 215 may be a hole formed by making a thin cut in the cartridge body 210. The guide slit 215 may be formed long in the front-back direction from the rear of the cartridge body 210 to one front side. The guide slit 215 may be formed to penetrate the cartridge body 210 upward and downward while having its rear end open. One guide slit 215 may be formed on each of the left and right sides of the elastic piece 211. The two guide slits 215 may be arranged to be left and right symmetrical with respect to the elastic piece 211. The two guide slits 215 can divide the rear portion of the cartridge body 210 into a left portion, a central portion, and a right portion. Guide slits 215 may be formed corresponding to the number and shape of the guide portions 115. The guide slit 215 serves to accurately guide the forward and backward sliding of the cartridge body 210 through insertion or separation from the guide portion 115 when the cartridge body 210 is inserted into or removed from the slot 113. can do.

A receiving hole 217 may be formed in the cartridge body 210. The receiving hole 217 may be formed to penetrate the cartridge body 210 in the vertical direction. The receiving hole 217 may be formed to be stepped so that the transverse cross-sectional area of the lower end is larger than the transverse cross-sectional area of the upper part. The number of receiving holes 217 may correspond to the number of assembly holes 119. For example, the receiving hole 217 may be formed on the front side of the left portion of the cartridge body 210 and on the front side of the right portion of the cartridge body 210, respectively. The receiving hole 217 is located directly below the assembly hole 119 formed on the upper surface of the first body portion 110 when the cartridge body 210 is inserted into the slot 113. may be in communication with The receiving hole 217 may be formed such that a portion of the horizontal cross-section in the height direction is smaller than the horizontal cross-section of the remaining portion excluding the portion. The assembly nut 220 can be accommodated in the receiving hole 217.

The receiving hole 217 may include a first hole 217a and a second hole 217b. The first hole 217a may be located above the second hole 217b. The top and bottom height (top and bottom length) of the first hole 217a may be longer than the top and bottom height (top and bottom length) of the second hole 217b. The first hole 217a may directly communicate with the lower end of the assembly hole 119. The second hole 217b may directly communicate with the lower end of the first hole 217a. The second hole 217b may be formed to extend outward along the lower end of the first hole 217a. That is, the transverse cross-sectional area of the second hole 217b may be larger than the transverse cross-sectional area of the first hole 217a. The first hole 217a may be formed in the form of a long hole having a first long axis. The first hole 217a may be formed to be long in the front-to-back direction. The first long axis of the first hole 217a may be the front-to-back length of the first hole 217a. The length of the first long axis of the first hole 217a may be longer than the outer diameter of the nut portion 221. The first hole 217a may have an opening on the upper surface of the cartridge body 210. The nut portion 221 of the assembly nut 220 can be accommodated in the first hole 217a. The upper end of the first hole 217a may face the lower end of the assembly hole 119. The first hole 217a may be formed in the same shape as the assembly hole 119. The second hole 217b may be formed in the form of a long hole having a second long axis. The second hole 217b may be formed to be long in the front-to-back direction. The second major axis of the second hole 217b may be the front-to-back length of the second hole 217b. The length of the second major axis of the second hole 217b may be longer than the length (front-rear length) of the flange portion 223 along the second major axis direction of the second hole 217b. The second hole 217b may be formed in a shape in which a portion of the left portion and a portion of the right portion of the circular hole are cut out to be symmetrical. The second hole 217b may have an opening on the lower surface of the cartridge body 210. The opening of the second hole 217b may be formed to be wider than the opening of the first hole 217a. The flange portion 223 of the assembly nut 220 can be accommodated in the second hole 217b.

Cartridge 200 may include an assembly nut 220. The assembly nut 220 may be provided for coupling between the cartridge 200 and the solar power generation facility (B). The assembly nut 220 may be received in the receiving hole 217 from the bottom to the top through the opening of the second hole 217b. For example, a portion of the assembly nut 220 may be accommodated in the first hole 217a, and the remaining portion may be accommodated in the second hole 217b. The assembly nut 220 may be formed to be stepped so that the transverse cross-sectional area of the lower end is larger than the transverse cross-sectional area of the upper part.

The assembly nut 220 may include a nut portion 221. The nut portion 221 may be formed in a hollow cylindrical shape. A thread for fastening to the solar power generation facility (B) may be formed on the inner peripheral surface of the nut portion 221. When the assembly nut 220 is accommodated in the receiving hole 217, the nut portion 221 may be accommodated in the first hole 217a of the receiving hole 217. The outer diameter of the nut portion 221 may be shorter than the length of the first long axis, which is the front-to-back length of the first hole 217a, and may be formed to be equal to the left and right lengths of the first hole 217a. The nut portion 221 is movable a certain distance in the front-back direction within the first hole 217a along the first long axis of the first hole 217a, which is formed in the shape of a long hole, and can adjust its position in the left-right direction. Movement to may not be possible. For example, the nut portion 221 may be movable by 3 mm toward the front or rear, respectively, based on the center of the first hole 217a. The top and bottom length of the nut portion 221 may be formed to be the same as the top and bottom length of the first hole 217a. The top of the nut portion 221 may be located at the same height as the top of the first hole 217a before fastening with the solar power generation facility (B), and when fastening with the solar power generation facility (B) is completed. , it can rise to the same height as the top of the assembly hole 119.

The assembly nut 220 may include a flange portion 223. The flange portion 223 may be formed in a shape in which a portion of the left portion and a portion of the right portion of the disk are cut out so that they are symmetrical. The flange portion 223 may be formed integrally with the nut portion 221. The flange portion 223 may extend outward along the lower end of the nut portion 221. That is, the transverse cross-sectional area of the flange portion 223 may be larger than the transverse cross-sectional area of the nut portion 221, so that the nut portion 221 may be formed in a stepped form with respect to the flange portion 223. When the assembly nut 220 is accommodated in the receiving hole 217, the flange portion 223 may be accommodated in the second hole 217b of the receiving hole 217. The left and right sides of the flange portion 223 may be in opposing contact with the inner left and right sides of the second hole 217b, respectively. As a result, the flange portion 223 may become unable to rotate inside the second hole 217b, and the assembly nut 220 including the flange portion 223 may also become unable to rotate inside the receiving hole 217. It can be a state. The front-to-back length of the flange portion 223 may be shorter than the length of the second major axis of the second hole 217b, and the left and right lengths of the flange portion 223 are the same as the left and right lengths of the second hole 217b. can be formed. The flange portion 223 is movable a certain distance in the front-back direction within the second hole 217b along the second long axis of the second hole 217b, which is formed in the shape of a long hole, so that its position can be adjusted in the left-right direction. Movement to may not be possible. For example, the flange portion 223 may be movable by 3 mm toward the front or rear, respectively, based on the center of the second hole 217b. The thickness (top and bottom length) of the flange portion 223 may be shorter than the top and bottom length of the second hole 217b.

The buoy 10 for solar power generation is assembled including a nut portion 221 and a flange portion 223 in a receiving hole 217 including a first hole 217a and a second hole 217b in the form of a long hole. The nut 220 is accommodated, and the assembly nut 220 is finely adjusted by 3 mm on one side within the receiving hole 217, that is, by 3 mm on the front and rear sides in the longitudinal direction based on the center of the receiving hole 217. Since this is possible, a degree of freedom is provided to the assembly nut 220 with respect to the longitudinal direction of the receiving hole 217, and thus it is possible to respond to the tolerance of the buoy body 100 or the solar power generation facility (B), and solar power generation The coupling position of the solar power generation facility with respect to the buoy 10 can be finely adjusted as needed.

Referring to FIG. 5, the assembly nut 220 may be accommodated in the receiving hole 217 of the cartridge body 210 and accommodated in the slot 113 of the buoy body 100 while being non-rotatably restrained. The assembly nut 220 may be seated with the lower surface of the flange portion 223 in contact with the inner lower surface of the slot 113, and the upper surface of the flange portion 223 may be in contact with the inner upper surface of the second hole 217b. It may be in a state of separation from . Additionally, as for the assembly nut 220, the top of the nut portion 221 may be positioned at the same height as the top of the first hole 217a.

As described above, the solar power generation facility (B) may be fastened to the assembly nut 220 of the cartridge 200 accommodated in the slot 113. Referring to FIG. 6, the solar power generation facility (B) may be inserted through the assembly hole 119 at the top of the buoy body 100 and fastened to the assembly nut 220. The solar power generation facility (B) may be fastened to the nut portion 221 of the assembly nut 220 through screwing. When the photovoltaic power generation facility (B) is fastened to the nut portion 221 through screwing, the flange portion 223 seated on the inner lower surface of the slot 113 is connected to the left side of the second hole 217b. The nut portion 221, which is guided by the right side and can slide upward along the height of the second hole 217b, and is formed integrally with the flange portion 223, is located on the left and right sides of the first hole 217a. It can be guided by and slide upward. The sliding of the flange portion 223 and the nut portion 221 is performed until the upper surface of the flange portion 223 is in contact with the inner upper surface of the second hole 217b, thereby connecting the solar power generation facility (B) and the assembly nut ( 220) The agreement between them can be completed. The solar power generation buoy 10 is a cartridge by having the upper surface of the flange portion 223 come into contact with the inner upper surface of the second hole 217b when fastening between the solar power generation facility (B) and the assembly nut 220 is completed. Stress applied to the body 210 and the first body portion 110 can be distributed and durability improved.

Referring to Figure 7, a filler 300 may be inserted into the buoy body 100. The filler 300 may be inserted into the internal spaces 110a and 120a of the buoy body 100 in a matching form. The filler 300 is to be inserted into the first internal space 110a of the first body 110 and the second internal space 120a of the second body 120 before forming the double injection unit 130. You can. When forming the double injection portion 130, the filler 300 surrounds the first body portion 110 and the second body portion 120 and applies very high pressure of the injection molding machine to form the double injection portion 130. It can be in close contact with the inner surfaces of the first internal space 110a and the second internal space 120a. Because of this, the filler 300 can be firmly adhered to the inner surface of the buoy body 100 using the very large pressure of the injection molding machine for forming the double injection portion 130 without separate pressurizing equipment. When polyethylene (PE, Polyethylene) is applied to the buoy body 100, the filler 300 may be expanded polyethylene (EPE, Expanded Polyethylene), a material of the same series, and polypropylene (PP) to the buoy body 100. , Polypropylene), expanded polyethylene (EPP), a material of the same series, can be applied. In this way, the buoy body 100 and the filler 300 can be manufactured from the same series of materials, thereby enhancing recyclability and eco-friendliness.

Figure 8 is an exploded perspective view showing a filler of a different type from the filler in Figure 7.

Referring to FIG. 8, the filler 300' may include a filler body 320 having a shape that matches the internal spaces 110a and 120a of the buoy body 100, and a filler cover 310. The filler body 320 may form a space with one side open. The upper surface of the space of the filler body 320 may be open. The filler cover 310 may cover one open surface of the filler body 320. That is, the filler cover 310 can be placed on top of the filler body 320 to close the open upper surface of the filler body 320. The filler cover 310 can be inserted into the first body 110, and the top and bottom of the filler body 320 can be inserted into the first body 110 and the second body 120, respectively. You can. The filler cover 310 and the filler body 320 are formed in the first internal space 110a of the first body 110 and the second interior of the second body 120 before forming the double injection unit 130. It may be inserted into space 120a. When forming the double injection portion 130, the filler cover 310 and the filler body 320 surround the first body portion 110 and the second body portion 120 to form the double injection portion 130. It can be brought into close contact with the inner surfaces of the first internal space (110a) and the second internal space (120a) by the very large pressure of the injection molding machine. In addition, the filler cover 310 and the filler body 320 are in close contact with each other, so that the space formed inside the filler body 320 can be sealed from the outside. Because of this, the possibility of water flowing into the space formed inside the filler body 320 may be significantly reduced.

Figures 9 (a) to (c) are perspective views showing various embodiments other than the first body portion according to an embodiment of the present invention.

Referring to Figures 9 (a) to (c), at least one of the first body portions 110, 110', and 110" and the second body portion 120 is optionally provided with a plurality of different shapes. It may be applicable by change. For example, as shown in (a) to (c) of Figure 9, the first body portion (110, 110', 110) in the buoy body (100, 100', 100") ") may be provided as an optional part having a plurality of different shapes. At this time, the second body 120, the double injection unit 130, and the cartridge 200 are shown in (a) of FIG. 9 to In (c), they can all be provided with the same common parts.The first body portion 110 shown in (a) of Figure 9 is the first body portion 110 according to an embodiment of the present invention described above. The first body portions 110' and 110" shown in Figures 9(b) and 9(c) are the first body parts 110' and 110" according to another embodiment of the present invention. ). The first body portion 110 shown in (a) of Figure 9 may be formed to have a longer vertical length than the first body portion 110' shown in (b) of Figure 9, The first body portion 110' shown in (b) of FIG. 9 is formed so that the upper and lower lengths are longer than the first body portion 110" shown in (c) of FIG. 9 (c). 110, 110', 110") may be provided. Each of the first body portions 110, 110', 110" shown in (a) to (c) of Figure 9 is (a) of Figure 9. , the height may be configured to decrease in the order of Figure 9 (b) and Figure 9 (c). In this way, the first body portions 110, 110', 110" can be provided in various shapes, and the remaining components except the first body portions 110, 110', 110" can be used for common use. , buoy bodies (100, 100', 100") of different sizes and with various buoyancy can be produced with less investment cost. In addition, the buoy bodies (100, 100', 100") can be selected as optional parts as needed. The first body portions 110, 110', and 110" can be selectively changed and combined with common parts.

Figure 10 is a perspective view showing a stacked state of buoys for solar power generation according to an embodiment of the present invention.

Referring to FIG. 10, a plurality of buoys 10 for solar power generation may be provided and stacked. The buoy body 100 has a plurality of protrusions 121 formed on the other buoy body 100 mounted on and seated on the plurality of depressions 111 formed on one buoy body 100. Layers may be laminated. In this case, the protrusion 121 of the buoy body 100 located at the top is supported by the depression 111 of the buoy body 100 located at the bottom, and the depression of the buoy body 100 located at the bottom Movement in the horizontal direction is restricted by being caught on side step surfaces between the part 111 and the upper surface, so that a plurality of solar power generation buoys 10 can be stacked while being stably stacked. In this way, the plurality of stacked solar power generation buoys 10 are lifted by inserting the fork part of a forklift or handcar into the receiving portion 123 of the solar power generation buoy 10 located at the lowest level. A plurality of buoys can be lifted together, and thus, a plurality of solar power generation buoys 10 can be transported at once or loaded and unloaded at a specific location, making mechanized loading and unloading work possible.

As described above, although the present invention has been described with limited examples and drawings, the present invention is not limited thereto, and the technical idea of the present invention and the following will be understood by those skilled in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of equivalence of the claims to be described.

10: Buoy for solar power generation 100, 100', 100": Buoy body
110, 110', 110": first body portion 110a: first internal space
111: depression 113: slot
115: Guide part 117: Holding hole
119: Assembly hole 120: Second body portion
120a: second internal space 121: protrusion
123: receiving part 130: double injection part
200: cartridge 210: cartridge body
211: elastic piece 211a: incision
213: Button portion 215: Guide slit
217: Receiving hall 217a: Hall 1
217b: second hole 220: assembly nut
221: nut portion 223: flange portion
300, 300': Filler 310: Filler cover
320: Filler body B: Solar power generation facility

Claims (19)

delete delete delete delete delete In the solar power generation buoy (10) assembled with the solar power generation facility (B) for solar power generation on the water,
Buoy body (100);
It includes a cartridge 200 coupled to the buoy body 100 to which the solar power generation facility (B) is assembled,
The cartridge 200 is removable from the buoy body 100,
A slot 113 is formed in the buoy body 100,
The cartridge 200 is inserted and mounted in the slot 113,
The slot 113 is formed on the upper part of at least one side of the buoy body 100,
The cartridge 200 is inserted horizontally into the slot 113,
The cartridge 200,
A cartridge body 210 having a receiving hole 217 formed through the vertical direction;
It includes an assembly nut 220 accommodated in the receiving hole 217 and inserted into the slot together with the cartridge body 210 while being non-rotatably restrained,
An assembly hole 119 communicating with the slot 113 is formed on the upper surface of the buoy body 100,
The assembly hole 119 communicates with the receiving hole 217 when the cartridge body 210 is inserted into the slot 113,
The solar power generation facility (B) is assembled with the assembly nut 220 through the assembly hole 119,
The receiving hole 217 is,
a first hole (217a) communicating with the lower end of the assembly hole (119) and formed in the form of a long hole having a first long axis;
It includes a second hole (217b) extending outward along the lower end of the first hole (217a) and formed in the shape of a long hole having a second long axis,
The assembly nut 220 is,
a nut portion 221 accommodated in the first hole 217a and adjustable in the first long axis direction;
A flange portion 223 that extends outward along the lower end of the nut portion 221 and is accommodated in the second hole 217b and is adjustable in the second long axis direction.
Buoy for solar power generation.
According to clause 6,
The length of the first long axis is longer than the outer diameter of the nut portion 221,
The length of the second long axis is formed to be longer than the length of the flange portion 223 along the second long axis direction,
Buoy for solar power generation.
According to clause 6,
The height of the second hole 217b is formed to be longer than the thickness of the flange portion 223,
The flange portion 223 rises along the second hole 217b when fastened between the assembly nut 220 and the solar power generation facility (b) and hangs on the inner upper surface of the second hole 217b.
Buoy for solar power generation.
In the solar power generation buoy (10) assembled with the solar power generation facility (B) for solar power generation on the water,
Buoy body (100);
It includes a cartridge 200 coupled to the buoy body 100 to which the solar power generation facility (B) is assembled,
The cartridge 200 is removable from the buoy body 100,
A slot 113 is formed in the buoy body 100,
The cartridge 200 is inserted and mounted in the slot 113,
The slot 113 is formed on the upper part of at least one side of the buoy body 100,
The cartridge 200 is inserted horizontally into the slot 113,
The cartridge 200,
A cartridge body 210 having a receiving hole 217 formed through the vertical direction;
It includes an assembly nut 220 accommodated in the receiving hole 217 and inserted into the slot together with the cartridge body 210 while being non-rotatably restrained,
A locking hole 117 communicating with the slot 113 is formed on the upper surface of the buoy body 100,
The cartridge body 210 includes an elastic piece 211 that is elastically deformable,
A button portion 213 is formed on the elastic piece 211 to enable attachment or detachment of the cartridge 200 by being engaged or released from the locking hole 117.
Buoy for solar power generation.
According to clause 6 or 9,
A plate-shaped guide portion 115 is formed in the slot 113,
A guide slit 215 into which the guide portion 115 is inserted is formed in the cartridge 200.
Buoy for solar power generation.
According to clause 6 or 9,
The buoy body 100,
A first body portion 110 having a first internal space 110a in which an open surface is formed;
A second body portion 120 having a second internal space 120a in which an open surface is formed;
The open side edge of the first body portion 110 is formed by an injection molding machine so that the open side edge of the first body portion 110 and the open side edge of the second body portion 120 are joined in a state of contact. And a double injection portion 130 formed by double injection in a shape surrounding the edge of the open surface side of the second body portion 120.
Buoy for solar power generation.
According to clause 11,
Before forming the double injection unit 130, fillers 300 and 300' are inserted into the first internal space 110a and the second internal space 120a,
When forming the double injection portion 130, the filler 300 is in close contact with the inner surfaces of the first internal space 110a and the second internal space 120a by the pressure of the injection molding machine.
Buoy for solar power generation.
According to clause 12,
The filler 300' is,
A filler body 310 in which a space with one side is open is formed;
A filler cover 320 covering the open surface of the filler body 310,
The filler body 310 and the filler cover 320 are in close contact with each other and sealed by the pressure of the injection molding machine,
Buoy for solar power generation.
According to clause 11,
At least one of the first body portion 110 and the second body portion 120 is provided in plural pieces with different shapes and can be selectively changed and applied,
Buoy for solar power generation.
According to clause 11,
The double injection unit 130 is formed in a different color from the buoy body 100,
Buoy for solar power generation.
According to clause 11,
A luminescent pigment is applied to the double injection unit 130,
Buoy for solar power generation.
According to clause 6 or 9,
On the lower surface of the buoy body 100, a receiving portion 123 is formed concavely in a shape that intersects the longitudinal direction of the buoy body 100,
The receiving portion 123 is formed in a pair parallel to each other,
Buoy for solar power generation.
According to clause 6 or 9,
On the upper surface of the buoy body 100, a plurality of depressions 111 concave downward are formed,
On the lower surface of the buoy body 100, a plurality of protrusions 121 protruding downward are formed,
Buoy for solar power generation.
According to clause 18,
The buoy body 100 has a form in which the plurality of protrusions 121 formed in the other buoy body 100 are seated in the plurality of depressions 111 formed in one of the buoy bodies 100. Multiple pieces can be stacked,
Buoy for solar power generation.

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