KR20230143853A - Underwater light for farm - Google Patents

Abstract

An underwater light according to the embodiment includes: a plurality of light source modules in which a plurality of LEDs are arranged; a base in the form of a prism, in which a hollow and a fastener rail are formed within the hollow, and the light source modules are disposed on the surface; an upper cover and a lower cover connected to one end and the other end of the base; a housing including a transparent window fixed by the upper cover and the lower cover; and a fastener inserted into the fastener rail to waterproofly fasten the base, the upper cover, the lower cover, and the transparent window, and the hollow is exposed to the water for heat generated by the light source modules to be dissipated into the water.

Description

{UNDERWATER LIGHT FOR FARM}

This technology is related to underwater lights for fish and shellfish farms.

As demand for farmed marine products increases globally, the size of the global aquaculture industry will increase by approximately 37.5% in 2030 compared to 2016 based on production volume, and the global economic ripple effect of aquaculture technology as of 2025 is estimated to reach approximately KRW 223 trillion. Growth potential is high.

However, Korea's aquaculture industry and fisheries industry are experiencing worsening management conditions due to a decrease in fishing population and workforce shortage due to aging, climate change, decline in fishery production due to decline in fisheries resources, and high-cost, low-efficiency structure.

In order to overcome these management difficulties, it is necessary to introduce technology that can improve productivity. One of the technologies to improve productivity is receiving attention as an underwater light that irradiates light to aquatic organisms to be cultured. For example, according to a study on fish growth using LED lighting in a land-based fish farm cultivating flounder fish, it was confirmed that there is an effect of promoting fish growth.

However, these LED lights emit light from above the water surface of land-based fish farms, and the light does not reach the depth where the aquatic organisms being farmed are located due to optical phenomena such as reflection from the water surface. Therefore, in order to provide light to the depth where aquatic life is located, a large amount of light must be irradiated to the water surface with high power, but it is difficult to improve productivity due to phenomena such as reflection from the water surface and light attenuation in the water.

This embodiment is intended to solve the difficulties of the prior art described above. In other words, one of the problems to be solved by this embodiment is to improve the productivity of aquatic organisms to be cultured by providing light underwater.

The underwater light according to this embodiment includes a plurality of light source modules in which a plurality of LEDs are arranged; A hollow and a fastener rail are formed within the hollow, a base in the form of a prism on which the light source modules are disposed, an upper and lower cover connected to one end and the other end of the base, and the upper cover; A housing including a transparent window fixed by the lower cover, and a fastener inserted into the fastener rail to waterproofly fasten the base, the upper cover, the lower cover, and the transparent window, wherein the light source modules are generated. The cavity is exposed to the water to dissipate heat into the water.

According to one aspect of this embodiment, a cable grand through which a power line that provides driving power to the plurality of light source modules is introduced is formed on the upper cover.

According to one aspect of this embodiment, a connecting member to which an underwater fixing member that limits movement of the underwater light is connected is further formed on the lower cover.

According to one aspect of this embodiment, the LED emits one or more colors of R (red), G (green), B (blue), W (white), cyan, and ultraviolet (UV). do.

According to one aspect of this embodiment, the fastener is a headless bolt protruding from the surface of the upper cover, and the underwater light is a nylon nut and a dome fastened to the headless bolt protruding from the surface of the upper cover. It further includes a cap nut (dome cap nut).

According to one aspect of this embodiment, the fastener is a headless bolt, and the underwater light further includes a nylon nut and a dome cap nut fastened to the headless bolt protruding from the surface of the lower cover.

According to one aspect of this embodiment, the fastener is a heat pipe that receives heat transferred from the light source modules to the base, distributes it to the base, and radiates heat to the water.

According to one aspect of this embodiment, the underwater light further includes an upper waterproof packing located between the upper cover and the transparent housing, and a lower waterproof packing located between the lower cover and the transparent housing.

According to one aspect of this embodiment, the underwater light is installed in a marine cage fish farm.

According to one aspect of the present embodiment, the upper cover further includes at least one of an upper fixing member connected to one or more of marine fixtures, buoys, and other underwater lights, and a water depth adjustment member capable of adjusting the water depth at which the underwater light is located. Includes.

According to one aspect of this embodiment, the lower cover further includes at least one of a lower fixing member connected to the underwater fixing member and a water depth adjustment member capable of adjusting the water depth at which the underwater light is located.

According to one aspect of this embodiment, a plurality of protrusions having different heights are formed in the hollow.

According to one aspect of this embodiment, the hollow surface is treated with an antifouling paint.

According to this embodiment, the advantage of being placed in a fish farm is that light can be provided to promote the growth of aquatic organisms to be cultivated.

Figure 1 is a perspective view of the underwater light of this embodiment.
FIG. 2 is a diagram illustrating an outline of an underwater light omitting the transparent window.
Figure 3 is a diagram showing a state in which a fastener is fastened to the base.
Figure 4 is a diagram illustrating a state in which the upper waterproof packing and the lower waterproof packing are combined with the fastener fastened to the base.
Figure 5 is a diagram schematically illustrating a state in which the underwater light according to this embodiment is placed below the water surface of a fish farm, such as a cage fish farm.
Figure 6(a) is a diagram illustrating a state in which protrusions having different heights are formed in the hollow of an underwater lamp, and Figure 6(b) is a diagram illustrating a state in which shellfish lamps are attached inside the hollow.

Hereinafter, this embodiment will be described with reference to the attached drawings. Figure 1 is a perspective view of the underwater light 10 of this embodiment, Figure 2 is a diagram showing an outline of the underwater light 10 omitting the transparent window 800, and Figure 3 is fastened to the base 120. It is a drawing showing a state in which the sphere 310 is fastened, and FIG. 4 is a drawing illustrating a state in which the fastener 310 is fastened to the base 120 and the upper waterproof packing and the lower waterproof packing are combined.

1 to 4, the underwater light 10 includes a plurality of light source modules 110a, 110b, and 110c in which a plurality of LEDs (L) are arranged; A hollow 122 and a fastener rail 124 are formed within the hollow 122, a prismatic base 120 on which the light source modules 110a, 110b, and 110c are disposed, and the base A housing including an upper cover 130 and a lower cover 140 connected to one end and the other end of (120) and a transparent window 800 fixed by the upper cover 130 and the lower cover 140, and It includes a fastener 310 that is inserted into the fastener rail 124 and waterproofly fastens the base 120, the upper cover 130, the lower cover 140, and the transparent window. In the underwater light 10, the hollow 122 is exposed to water so that heat generated by the light source modules 110a, 110b, and 110c is dissipated into water.

In the light source modules 100a, 100b, and 100c, LEDs (L) that emit light are electrically connected, and driving power is provided to provide light. In one embodiment, the LEDs (L) included in the light source modules 100a, 100b, and 100c may provide light in a predetermined wavelength band. For example, each LED (L) has R (red), G Any one of (green), B (blue), cyan, white light (w), and ultraviolet (UV) light can be provided. A lens may be attached to each LED (L), and when the underwater light (10) is placed underwater to provide light, it is possible to provide an even distribution of light in the surrounding area.

The base 120 is formed in the shape of a prism, and light source modules 100a, 100b, and 100c may be arranged on each surface of the prism. The light source modules 100a, 100b, and 100c may be in direct contact with the base 120, or may be disposed on the surface of the base 120 with a non-electrically conductive, but highly thermally conductive material interposed therebetween.

In the illustrated embodiment, the base 120 is illustrated in the form of a hexagonal pillar. However, this is only an example, and the base may have the shape of an n-cornered pillar (n: a natural number), such as a hollow triangular pillar, square pillar, or pentagonal pillar.

Base 120 has a hollow 122. In the illustrated example, the hollow 122 is a hexagonal pillar like the shape of the base 120, but in another embodiment, the hollow 122 may be formed with a circular cross-section. The hollow 122 is formed to contact water but prevent moisture from penetrating into the surface where the light source modules 100a, 100b, and 100c are arranged. The heat generated by the light source modules 100a, 100b, and 100c while providing light is transferred to the base 120 and dissipated into the water located in the hollow 122. Water penetrating into the hollow 122 is heated and dissipated to the outside of the hollow 122 by a convection phenomenon, and unheated water flows into the hollow 122 to continuously cool the base.

Therefore, the underwater light 10 according to this embodiment has high heat dissipation performance and can prevent damage to the LED due to heat dissipation problems. Furthermore, the heat dissipation performance of the underwater light 10 according to this embodiment provides the advantage of improving the light provision efficiency of the LED.

A fastener rail 124 on which the fastener 310 is located is formed in the hollow 122 of the base 120. The fastener 310 may be inserted into and fixed to the fastener rail 124. In one embodiment, the fastener 310 may be a headless bolt and may be inserted into the fastener rail 124. The fastener 310 may protrude from the upper cover 130 and/or lower cover 140 by a predetermined length.

In one embodiment, a nut insertion hole is formed in the upper cover 130, and a nylon nut 312 is inserted into the nut insertion hole and fastened to the fastener 310. The fastener 310 is screwed and fastened to the nylon nut 312, and the fastener 310 protruding above the nylon nut 312 is a dome cap nut. , 314) and screwed together. Likewise, an insertion hole is formed in the lower cover 130 to insert the nylon nut 312, and the fastener 310 is screwed and fastened to the nylon nut 312. The fastener 310 protruding above the nylon nut 312 is screw-coupled with the dome cap nut 314.

In one embodiment, the fastener 310 may be a heat pipe made of a material with high thermal conductivity, such as copper or aluminum. Heat generated when the light source modules 100a, 100b, and 100c emit light is transferred to the base 120. The heat transferred to the base 120 may be transferred to the fastener 310, which is a heat pipe, through the fastener rail 124. The fastener 310, which is a heat pipe, evenly distributes heat throughout the base 120, and can cool the base 120 with water penetrating into the hollow 122.

A waterproof packing 430 may be positioned between the upper cover 130 and the transparent window 800, and a waterproof packing 430 may be positioned between the lower cover 140 and the transparent window 800. In one embodiment, a groove 432 may be formed in the waterproof packing 430 to position the transparent window 800. The end of the transparent window 800 is seated in the groove 432 formed in the waterproof packing 430, thereby improving airtightness. From this, the underwater light 10 can have high waterproof performance.

The lower cover 130, upper cover 140, and transparent window 800 are fastened to the fastener 310 to form a waterproof housing, and can have high waterproof properties due to the waterproof packing 430. Additionally, the double fastening structure of the fastener 310, the nylon nut 312, and the dome cap nut 314 provides the advantage of achieving higher fastening strength.

The illustrated embodiment illustrates that the fastener 310 protrudes from the surfaces of the lower cover 130 and the upper cover 140 and is screw-coupled with the nylon nut 312 and the dome cap nut 314. However, according to an embodiment not shown, the fastener is coupled to a nut formed inside one of the lower cover 130 and the upper cover 140. The other side that is not fastened protrudes to the outside and can be fastened with a nylon nut and a dome cap nut to form a waterproof housing.

In the illustrated embodiment, a cable gland 500 through which a power line 600 (see FIG. 5) is inserted may be formed on the upper cover 130. In one embodiment, the cable gland 500 is formed by screwing the packing (not shown) located at the inlet where the power line (not shown) enters, and the power line (not shown) and the cable gland (500) are connected. ) can minimize the inflow of seawater through the gap.

Figure 5 is a diagram schematically illustrating a state in which the underwater light 10 according to this embodiment is placed below the water surface of a fish farm, such as a cage fish farm. 1 to 5, marine fixtures (S) may be placed in the fish farm, and buoys (B) may be located between the marine fixture (S) and the marine fixture (S).

The marine fixture (S) may be equipped with power devices such as a battery (not shown) that provides direct current power and a switching mode power supply (SMPS) that boosts or reduces the voltage provided by the battery. Direct current power provided by the power supply device may be provided to the underwater light 10 through the power line 600, and enters the underwater light 10 through the cable gland 500 formed in the underwater light 10 as described above. It is possible to provide driving power to the LED (L) included in the underwater light (10).

The underwater light 10 located underwater may be affected by currents, waves, etc. Therefore, it is necessary to prevent movement such as drifting due to currents and waves. An upper fixing member 710 may be formed on the upper cover 130, which is connected to a marine fixture (S), a buoy (B), and another underwater light (10) through a tether, rope, chain, etc.

In one embodiment, the upper fixing member 710 is a ring-shaped structure located on the upper cover 130, and is used for marine fixtures (S), buoys (B), and other underwater lights (10), as illustrated in Figure 5. and can be connected through ropes, ropes, etc. In addition, the upper cover 130 may further include a water depth adjustment member (not shown) that can adjust the water depth at which the underwater light 10 is located. As an example, the water depth adjustment member may have the form of a clamp member, a tong member, etc. that secures a tether, rope, or chain connected to marine fixtures, buoys, and other underwater lights.

The lower cover 140 may further include a lower fixing member 720 connected to the underwater fixing member W to prevent the underwater light 10 from moving below the water surface. In the illustrated example, the underwater fixing member (W) is a weight member (W) connected to the underwater light (10) and having a weight capable of minimizing movement. In an embodiment not shown, the underwater fixing member is a member fixed to the surface of the sea bottom, and the member fixed to the surface of the sea bottom is connected to the lower fixing member 720 with a tether, rope, chain, etc. to fix the underwater light.

In one embodiment, the lower fixing member 720 is a ring-shaped structure located on the lower cover 140, and can be connected to the underwater fixing member (w) through a rope, rope, chain, etc., as illustrated in Figure 5. there is. In addition, the lower fixing member 720 may further include a water depth adjustment member (not shown) that can adjust the water depth at which the underwater light 10 is located. As an example, the water depth adjustment member may have the form of a clamp member, a tong member, etc. that secures a tether, rope, or chain connected to marine fixtures, buoys, and other underwater lights.

If the underwater light 10 is placed and used in a fish farm for a long time, shellfish, algae, and sediment may attach to the hollow interior. As a result, the area where water flowing through the hollow contacts the base is reduced, and heat dissipation performance may deteriorate.

According to one embodiment, the hollow 122 of the underwater light 10 is treated with an anti-fouling paint to prevent aquatic organisms such as shellfish and algae from attaching and growing inside. In one embodiment, the antifouling paint may be an eco-friendly paint containing copper powder.

As in the embodiment illustrated in FIG. 6(a), protrusions 126 having different heights may be formed in the hollow 122 of the underwater light 10. As in the illustrated embodiment, the protrusions 126 may have a cone shape with sharp ends, and as in the not-illustrated embodiment, the protrusions may have a prismatic shape such as a cylinder or square pillar. The protrusions 122 formed within the hollow 122 and the surface of the hollow 122 may be treated with an antifouling paint.

Figure 6(b) is a diagram illustrating a state where shellfish (C), etc. are attached inside the hollow 122. Referring to FIG. 6(b), shellfish (C), etc. may be attached to the protrusion 126 inside the hollow 122. However, as in the illustrated embodiment, the area where the shellfish (C) contact the inside of the hollow 122 can be reduced by the protrusions 126 having different heights. From this, in addition to the advantage of being able to suppress the growth of shellfish (C), the advantage of being able to easily remove the shellfish (C) attached to the hollow 122 is provided.

Although the present invention has been described with reference to the embodiments shown in the drawings to aid understanding, these are embodiments for implementation and are merely illustrative, and those skilled in the art will be able to make various modifications and equivalents therefrom. It will be appreciated that other embodiments are possible. Therefore, the true technical protection scope of the present invention should be determined by the attached patent claims.

10: underwater light
100a, 100b, 100c: light source module 120: base
122: hollow 124: fastener rail
130: upper cover 140: lower cover
310: Fastener 312: Nylon nut
314: Dome cap nut 430: Waterproof packing
432: Home 500: Cable gland
600: power line 710: upper fixing member
720: Lower fixing member 800: Transparent window
126: protrusion

Claims (13)

A plurality of light source modules in which a plurality of LEDs are arranged;
a base in the form of a prism, in which a hollow and a fastener rail are formed within the hollow, and the light source modules are disposed on the surface;
An upper cover and a lower cover connected to one end and the other end of the base, and
A housing including a transparent window fixed by the upper cover and the lower cover, and
It includes a fastener inserted into the fastener rail to waterproofly fasten the base, the upper cover, the lower cover, and the transparent window,
An underwater light in which the hollow part is exposed to the water to dissipate heat generated by the light source modules into the water. According to paragraph 1,
In the upper cover
An underwater light having a cable grand through which a power line that provides driving power to the plurality of light source modules is introduced. According to paragraph 1,
In the lower cover
An underwater light further comprising a connecting member to which an underwater fixing member that limits movement of the underwater light is connected. According to paragraph 1,
The LED is,
An underwater light that emits one or more of the following colors: R (red), G (green), B (blue), W (white), cyan, and ultraviolet (UV). According to paragraph 1,
The fastener is,
It is a headless bolt protruding from the surface of the upper cover,
The underwater light is,
An underwater light further comprising a nylon nut and a dome cap nut fastened to a blunt bolt protruding from the surface of the upper cover. According to paragraph 1,
The fastener is,
It is a headless bolt,
The underwater light is,
An underwater light further comprising a nylon nut and a dome cap nut fastened to the headless bolt protruding from the surface of the lower cover. According to paragraph 1,
The fastener is,
An underwater light that is a heat pipe that receives the heat delivered by the light source modules to the base, distributes it to the base, and radiates heat to the water. According to paragraph 1,
The underwater light is,
An upper waterproof packing located between the upper cover and the transparent housing,
An underwater light further comprising a lower waterproof packing located between the lower cover and the transparent housing. According to paragraph 1,
The underwater light is,
An underwater light installed in marine cage fish farms. According to paragraph 1,
In the upper cover
An upper fixing member connected to any one or more of marine fixtures, buoys and other underwater lights; and
An underwater light further comprising one or more of the water depth adjustment members capable of adjusting the water depth at which the underwater light is located. According to paragraph 1,
In the lower cover
A lower fixing member connected to the underwater fixing member and
An underwater light further comprising one or more of the water depth adjustment members capable of adjusting the water depth at which the underwater light is located. According to paragraph 1,
In the hollow
An underwater light formed by a plurality of protrusions of different heights. According to paragraph 1,
The hollow surface is
Underwater lights treated with anti-fouling paint.