KR102118171B1 - Underwater lighting - Google Patents

Abstract

The present invention relates to an underwater lighting device which comprises: a light module unit having a plurality of light sources disposed in a longitudinal direction; a housing unit formed to surround a circumference of the light module unit; one cover member and the other cover member coupled to both side surfaces of the housing unit; a power supply unit transmitting power to the optical module unit; and a plurality of heat dissipation fin units formed at regular intervals on a lower part of the optical module unit. When the light emitted from the optical module unit is transmitted to the outside through the housing unit by the power transmitted from the power supply unit and high heat is generated from the optical module unit, the heat dissipation fin unit discharges the high heat by receiving the high heat.

Description

Underwater lighting device

The present invention relates to an underwater lighting device, and in particular, to facilitate the heat dissipation of the light emitters that emit light in the water, and at the same time, moisture is not generated in the interior, and an underwater lighting device capable of emitting high brightness illumination It is about.

In general, underwater lighting devices are installed in fountains in parks, ponds, rivers, etc., and are provided in a variety of forms to realize the surrounding environment. Especially, at night, water jetted from fountains can be more colorful. Doing.

In the conventional underwater lighting device as described above, high heat is generated in the LED lighting installed inside the main body, and such high heat causes a problem that the underwater lighting device fails due to overheating when not discharged outside the main body. .

Korean Registered Utility Model No. 20-0368484

An object of the present invention is to provide an underwater lighting device having a structure that effectively discharges heat generated inside the underwater lighting device.

The present invention is a plurality of light sources are arranged in the longitudinal direction of the optical module unit, the housing unit formed to surround the periphery of the optical module unit, one side cover member and the other side cover member coupled to both sides of the housing portion, the optical module It includes a power supply unit for transmitting power to the unit and a plurality of heat sink fins formed at regular intervals below the optical module unit, and light emitted from the optical module unit by the power transmitted from the power supply unit is transmitted through the housing unit to the outside. In the meantime, when high heat is generated from the optical module unit, the heat dissipation fin unit receives the high heat and discharges it to the surroundings.

The heat dissipation fin portion may have an uneven line formed on the surface.

The one side cover member and the other side cover member are formed of a metal material having high thermal conductivity, so that the one side cover member is in close contact with one side of the optical module unit, and the other side cover member can be in close contact with the other side of the optical module unit.

The housing portion is wrapped around only the upper and lower sides of the optical module portion, and is formed in an open state below the optical module portion. Can be formed.

A concave portion may be formed on the upper portion of the heat dissipation member to surround the lower portion of the heat dissipation fin portion.

A lower radiating portion in the form of a radiating fin may be formed under the radiating member.

A heat dissipation rod portion may be formed between the lower heat dissipation portion and the adjacent lower heat dissipation portion.

A portion of the heat dissipation fin portion is extended to form a heat dissipation fin extension portion, and a through hole through which the heat dissipation fin extension portion penetrates is formed in the housing portion, and an end of the heat dissipation fin extension portion may be exposed to the outside of the housing portion through a through hole.

The cover member is connected to the rotating shaft, the rotating shaft is formed with a rotating portion for rotating the rotating shaft, the rotating portion is a driven gear formed on the rotating shaft, a driving gear formed to be meshed with the driven gear, and driving the driving gear A drive motor can be formed.

An incision is formed in the housing portion in the longitudinal direction, a vertical conducting member is formed in the incision, and an upper part of the vertical conducting member is in contact with each of the lower surfaces of the heat dissipation fin parts, and a lower part of the vertical conducting member is located under the housing part Can be exposed.

According to the present invention, in addition to heat dissipation through one side cover member and the other side cover member, heat is discharged through the vertical conducting member, so that heat generated from a plurality of LEDs is rapidly discharged, thereby preventing an effect due to overheating. do.

In addition, according to the present invention, a heat dissipation structure is formed by an extension portion of one side of the heat radiation fin and an extension portion of the other side of the heat radiation fin, thereby generating an effect of rapid heat dissipation.

In addition, the present invention also has the effect of improving the durability of the lower heat dissipation portion by acting to support the heat dissipation portion between the lower heat dissipation portion and the action of increasing the heat dissipation area.

1 is a schematic perspective view showing a first embodiment of an underwater lighting device according to the present invention.
Figure 2 (a) is a schematic front sectional view showing a main configuration of a first embodiment of the present invention, the underwater lighting device, Figure 2 (b) is a schematic view showing a cross section of the portion A-A' in Figure 2 (a) It is a cross section.
3 is a schematic perspective view showing a structure for coupling one side cover member and the other side cover member.
FIG. 4(a) is a schematic front sectional view of an important part showing a second embodiment of the present invention underwater lighting device, and FIG. 4(b) is a schematic sectional view showing a section BB' in FIG. 4(a). It is a cross section.
FIG. 5(a) is a schematic front sectional view of an important part showing a third embodiment of the present invention underwater lighting device, and FIG. 5(b) is a schematic sectional view showing a CC′ part in FIG. 5(a). It is a cross section.
Fig. 6(a) is a schematic front sectional view of an important part showing a fourth embodiment of the present invention underwater lighting device, and Fig. 6(b) is a schematic sectional view showing a section DD' in Fig. 6(a). It is a cross section.
Fig. 7(a) is a schematic front sectional view of an important part showing a fifth embodiment of the luminaire for underwater lighting according to the present invention, and Fig. 7(b) is a schematic sectional view showing an EE' part in Fig. 7(a). It is a cross section.
FIG. 8(a) is a schematic front sectional view of an important part showing a sixth embodiment of the present invention underwater lighting device, and FIG. 8(b) is a schematic sectional view showing the section FF' in FIG. 8(a). It is a cross section.
9(a) is a schematic front sectional view of an important part showing a seventh embodiment of the present invention underwater lighting device, and FIG. 9(b) is a schematic sectional view showing a GG' part of FIG. 9(a). It is a cross section.

Hereinafter, various embodiments of the present invention will be described by specific embodiments illustrated in the accompanying drawings. Differences in the embodiments should not be mutually exclusive matters and should be understood in the drawings in combination, without departing from the spirit and scope of the present invention, specific shapes, structures, and properties described in connection with the embodiments are other embodiments Can be implemented as

The position or arrangement of individual components according to embodiments of the present invention should be understood as a combination of drawings to be changeable, and similar reference numerals in the drawings may refer to the same or similar functions across various aspects, and may include length and area, The thickness and the specific shape thereof may be exaggerated for convenience in description.

Each unit, module, part, member, or any structure in which the sub-elements are not described is assumed to include or include conventional sub-elements for each having a given function, and is limited to the sub-elements or detailed structures shown in the drawings. I don't.

Components shown, but whose description is omitted in the general content, should be understood as inherent in the detailed description of the embodiments.

An underwater lighting device according to one embodiment having high practical implementation and high industrial availability among various embodiments of the present invention will be described with reference to the above-mentioned conventional matters.

Hereinafter, main components of the underwater lighting apparatus according to an embodiment of the present invention will be described based on the drawings.

FIG. 1 is a schematic perspective view showing a first embodiment of the present invention underwater lighting device, and FIG. 2(a) is a schematic front sectional view showing a main configuration of a first embodiment of the present invention underwater lighting device. b) is a schematic cross-sectional view showing a cross section of part A-A' in Fig. 2A.

In the first embodiment of the present inventor underwater lighting device 100, a plurality of light source LEDs (LEDs) 112 are arranged in three lines along a longitudinal direction, and a long and short rectangular upper part of the optical module is formed. (110), a transparent material formed in a form surrounding the circumference of the optical module unit 110, the cylindrical housing portion 130, and one side cover member coupled to close both side surfaces of the housing portion 130 ( 150) and the other side cover member 160, one side support member 170 is formed to be mounted on the ground while supporting the one side cover member 150, and the other side cover member 160 is formed to be mounted on the ground while supporting It includes the other side support member 180 and the power supply unit 190 for transmitting power to the optical module unit 110.

The optical module unit 110 includes a plurality of LEDs 112, a substrate portion 114 having a predetermined thickness, which is arranged in three rows at the top, and a heat dissipation fin portion that is formed downward at a predetermined interval under the substrate portion 114 at a predetermined interval. (116).

The heat dissipation fin portion 116 is formed with a small uneven line 118 on the surface to maximize the heat dissipation area.

In the plurality of LEDs 112, when high heat is generated, the heat dissipation fin portion 116 serves to receive the high heat and discharge it to the surroundings.

The housing part 130 is formed of a transparent material and serves to transmit light to the LED 112 emitted from the optical module part 110 to the outside.

One side groove 152 is formed in the one side cover member 150 so that one side of the housing portion 130 is coupled, and the other side groove 162 is formed in the other side cover member 160 so that the other side of the housing portion 130 is coupled. When this is formed, one side of the housing portion 130 is introduced into one side groove 152, and the other side of the housing portion 130 is introduced into the other side groove 162, the inner space of the housing portion 130 is an external space And is blocked.

Through this, an effect capable of maintaining the lighting function while the LED 112 is installed underwater is generated.

And when both sides of the housing portion 130 is coupled to one side cover member 150 and the other side cover member 160, one side cover member 150 is in close contact with one side (110a) of the optical module unit 110, the other side cover member 160 is in close contact with the other side (110b) of the optical module unit 110, one side cover member 150 and the other side cover member 160 is formed of a metal material having a high thermal conductivity is generated in the optical module unit 110 Heat is transferred to one side cover member 150 and the other side cover member 160 to function to be discharged to the outside.

The present invention underwater lighting device 100 performs the lighting function in a state installed in the water, so the LED 112 of the optical module unit 110 performs a lighting function while preventing moisture from entering the housing unit 130 It is necessary to quickly dissipate the high-temperature heat generated in ), and in the first embodiment, the high-temperature heat generated in the LED 112 is discharged by the heat-radiating fin portion 116 formed in the optical module part 110, The one side cover member 150 and the other side cover member 160 function to quickly discharge heat generated inside the housing part 130 to the outside.

The other side cover member 160 is connected to the rotating shaft 210, the rotating shaft 210 is formed with a rotating portion 220 for rotating the rotating shaft 210.

The rotating part 220 includes a driven gear 222 formed on the rotating shaft 210, a driving gear 224 formed to be meshed with the driven gear 222, and a driving motor driving the driving gear 224 ( 226) is formed.

When the driving motor 226 is operated, the driven gear 222 is rotated by the rotation of the driving gear 224 while rotating the rotating shaft 210 to change the irradiated direction of the LED 112.

3 is a schematic perspective view showing a structure for coupling one side cover member and the other side cover member.

In the present invention, the structure in which the one side cover member 150 and the other side cover member 160 are coupled while the housing part 130 is coupled to the one side cover member 150 and the other side cover member 160 is one side cover member 150 ) A plurality of first through-holes 310 and a plurality of second through-holes 311 formed around the other cover member 160, the first through-holes 310 and the second through-holes 311 ) Is formed through a connecting rod 312 formed to penetrate between, and a threaded portion 314 coupled to both ends of the connecting rod 312.

In the present invention, the formation of the sealing structure of the housing part 130 includes the through holes 310 of the connecting rods 312 when the housing part 130 is coupled to the one side cover member 150 and the other side cover member 160. It is completed by fixing the both ends of the connecting rod 312 with the screw portion 314 after being drawn in.

FIG. 4(a) is a schematic front sectional view of an important part showing a second embodiment of the present invention underwater lighting device, and FIG. 4(b) is a schematic sectional view showing a section BB' in FIG. 4(a). It is a cross section.

The second embodiment of the inventor's underwater lighting device 100 is an improvement of the heat dissipation structure of the first embodiment, and the other parts are similar to those of the first embodiment and are mainly described for differences.

The incision part 410 is formed in the longitudinal direction at the bottom of the housing part 130, and a vertical conductive member 420 is formed in the incision part 410.

The upper portion of the vertical conductive member 420 is in contact with each of the lower surface of the heat dissipation fins 116, the lower portion of the vertical conductive member 420 is exposed to the lower portion of the housing portion 130.

A packing member 430 is formed between the vertical conductive member 420 and the incision part 410 of the housing part 130 to form an airtight between the vertical conductive member 420 and the incision part 410 of the housing part 130. This is maintained to form a waterproof function.

The material of the vertical conductive member 420 is formed of a high conductivity metal material such as one side cover member 150 and the other side cover member 160.

The vertical conductive member 420 serves to transfer heat transmitted from the heat dissipation fin portion 116 to the lower portion of the housing portion 130 to be quickly discharged into the water.

The present invention, in addition to heat dissipation through one side cover member 150 and the other side cover member 160 of the first embodiment through the second embodiment, the heat is released through the vertical conductive member 420, a plurality of LEDs 112 ) Generates heat quickly so that an effect can be prevented due to overheating.

FIG. 5(a) is a schematic front sectional view of an important part showing a third embodiment of the present invention underwater lighting device, and FIG. 5(b) is a schematic sectional view showing a CC′ part in FIG. 5(a). It is a cross section.

The third embodiment of the inventor's underwater lighting device 100 is an improvement of the heat dissipation structure of the second embodiment, and the rest is similar to that of the second embodiment, and focusing on differences.

In the third embodiment of the present inventor underwater lighting device 100, the lower portions of the heat dissipation fin portions 116 extend to both sides, thereby forming one extension portion 116-1 of the heat radiation fin and another extension portion 116-2 of the heat radiation fin. do.

And the housing portion 130 has one side through hole 132 through which the heat radiation fin one side extension portion 116-1 and the other side through hole 134 through the heat radiation fin other side extension portion 116-2 penetrate the housing portion ( 130) is formed in a plurality in the longitudinal direction.

Between the heat radiation fin one side extension portion 116-1 and the one side through hole 132, one side packing portion 136 is formed, the heat radiation fin between the other side extension portion 116-2 and the other side through hole 134. The other side packing part 138 is formed.

The end of the extension portion 116-1 on one side of the heat radiation fin and the end of the extension portion 116-2 on the other side of the heat radiation fin are exposed to the outside of the housing 130.

The heat radiation fin one side extension portion 116-1 and the heat radiation fin other side extension portion 116-2 receives heat transmitted from the heat radiation fin portion 116 and transmits the heat to the outside of the housing portion 130 to surround the housing portion 130. Heat dissipates quickly by flowing water.

The third embodiment of the present invention underwater lighting device 100, in addition to the heat dissipation structure by the vertical conductive member 420 of the second embodiment, the heat radiation fin one side extension portion 116-1 and the heat radiation fin other side extension portion 116-2. The heat dissipation structure is formed by the effect of rapid heat dissipation.

Fig. 6(a) is a schematic front sectional view of an important part showing a fourth embodiment of the present invention underwater lighting device, and Fig. 6(b) is a schematic sectional view showing a section DD' in Fig. 6(a). It is a cross section.

The fourth embodiment of the inventor's underwater lighting device 100 is an improvement in the heat dissipation structure of the first embodiment, and the rest of the lighting system is similar to the first embodiment, and the description will focus on differences.

The fourth embodiment of the inventors underwater lighting device 100 is a state in which the lower portion of the housing portion 130 is opened downward at a position slightly lower than the lower surface of the radiating fin portion 116, and the longitudinal direction of the housing portion 130 As a result, a horizontal heat radiation member 510 that is in contact with the entire bottom surface of the heat radiation fin portion 116 is formed.

That is, the housing unit 130 is a form surrounding only the upper and longitudinal sides of the optical module unit 110, and is formed in an open state below the optical module unit 110, and the housing unit 130 A horizontal heat dissipation member 510 is formed at an open portion of the housing to block the open portion of the housing portion 130.

The lower side of the housing 130 in the longitudinal direction is formed with one side inlet groove 512 into which one side of the horizontal heat dissipation member 510 is drawn, and the horizontal heat dissipation member ( 510) the other side of the inlet groove 514 is formed.

The one side cover member 150 is formed with one side cover groove 516 through which one end of the horizontal heat dissipation member 510 is introduced, and the other end of the horizontal heat dissipation member 510 is introduced into the other side cover member 160. The other side cover groove 518 is formed.

One side of the horizontal heat dissipation member 510 is introduced into the one side inlet groove 512, the other side of the horizontal heat dissipation member 510 is introduced into the other side inlet groove 514, one end of the horizontal heat dissipation member 510 When the other side of the horizontal heat dissipation member 510 is introduced into the one side cover groove 516, the lower portion of the housing 130 is closed by the horizontal heat dissipation member 510.

The horizontal heat dissipation member 510 is made of a metal material and has a high thermal conductivity.

The top surface of the horizontal heat dissipation member 510 is in contact with the entire bottom surface of the heat dissipation fin part 116, and transfers heat transmitted from the heat dissipation fin part 116 to water contacting the bottom surface of the horizontal heat dissipation member 510.

In the fourth embodiment of the present invention, the cross-sectional area of the housing 130 is reduced by the horizontal heat dissipation member 510 compared to the first to third embodiments, so that the inner space of the housing 130 is reduced. Although the space in which heat generated in (112) dwells is reduced, the heat dissipation effect is high because the entire bottom surface of the heat radiation fin portion (116) contacts the top surface of the horizontal heat radiation member (510).

Fig. 7(a) is a schematic front sectional view of an important part showing a fifth embodiment of the luminaire for underwater lighting according to the present invention, and Fig. 7(b) is a schematic sectional view showing an EE' part in Fig. 7(a). It is a cross section.

The fifth embodiment of the inventor's underwater lighting device 100 is an improvement of the heat dissipation structure of the fourth embodiment, and the rest is similar to that of the fourth embodiment, and focusing on differences.

The fifth embodiment of the present invention underwater lighting device 100 is a lower heat dissipation part in the form of a heat dissipation fin in the same position as the position where the heat dissipation fin part 116 is formed under the horizontal heat dissipation member 510 in the structure of the fourth embodiment ( 530) is formed.

That is, a plurality of lower heat dissipation portions 530 are formed along the longitudinal direction of the horizontal heat dissipation member 510, and the position of the first lower heat dissipation portion 530-1 of the lower heat dissipation portion 530 is the heat dissipation fin portion 116. Among the first radiating fin portion 116-1 is located in a portion extending downwardly, and the second lower radiating portion 530-2 is located in the second radiating fin portion 116-2 of the radiating fin portion 116. It is in the portion extending downward from the position, and the position of the Nth lower heat dissipation portion 530-N is in the portion extending downward from the position of the Nth heat dissipation fin portion 116-N of the heat dissipation fin portion 116.

Through the above-described structure, the fifth embodiment of the present invention quickly transfers heat from the first heat-radiating fin portion 116-1 to the horizontal heat-radiating member 510, and quickly to the first lower heat-radiating portion 530-1. The first lower heat dissipation portion 530-1 is in contact with water, and serves to quickly dissipate heat.

Of course, the heat transferred from the second heat-radiating fin portion 116-2 is quickly dissipated through the second lower radiating portion 530-2, and the heat transmitted from the N-heat radiating fin portion 116-N is the N-lower portion. It is quickly radiated through the heat dissipation portion (530-N).

FIG. 8(a) is a schematic front sectional view of an important part showing a sixth embodiment of the present invention underwater lighting device, and FIG. 8(b) is a schematic sectional view showing the section FF' in FIG. 8(a). It is a cross section.

The sixth embodiment of the inventor's underwater lighting device 100 is an improvement of the heat dissipation structure of the fifth embodiment, and the rest is similar to that of the fifth embodiment, focusing on differences.

In the sixth embodiment of the present inventor underwater lighting device 100, a first heat sink portion 610-1 is formed between a first lower heat dissipation portion 530-1 and a second lower heat dissipation portion 530-2. In addition, the remaining lower heat dissipation portion 530 is also formed with a heat dissipation rod portion 610 between the adjacent lower heat dissipation portion 530.

The first heat sink portion 610-1 increases the heat dissipation area to rapidly discharge heat transferred from adjacent first lower heat dissipation portions 530-1 and second lower heat dissipation portions 530-2. It also acts to support between the adjacent first lower heat dissipation portion 530-1 and the second lower heat dissipation portion 530-2, thereby generating an effect of improving the durability of the lower heat dissipation portion 530.

Three heat radiation rod portions 610 are formed between adjacent lower heat radiation portions 530, and can be formed by adjusting the number of heat radiation rod portions 610, if necessary.

9(a) is a schematic front sectional view of an important part showing a seventh embodiment of the present invention underwater lighting device, and FIG. 9(b) is a schematic sectional view showing a GG' part of FIG. 9(a). It is a cross section.

The seventh embodiment of the inventor's underwater lighting device 100 is an improvement of the heat dissipation structure of the fourth embodiment, and the rest is similar to that of the fourth embodiment, and focusing on differences.

In the seventh embodiment of the lighting device 100 for the present inventors, the lower portion of the housing portion 130 is opened downward at a position slightly lower than the lower surface of the heat radiating fin portion 116, and the longitudinal direction of the housing portion 130 In the form of surrounding the lower portion of the heat dissipation fin portion 116, uneven heat dissipation members 710 respectively contacting the entire lower portion of the heat dissipation fin portion 116 are formed.

One side of the uneven heat dissipation member 710 is formed on one lower side of the longitudinal direction of the housing portion 130, and the uneven heat dissipation is formed on the lower side of the other side of the housing 130 in the longitudinal direction. The other side of the concavo-convex indentation groove 714 is formed in which the other side of the member 710 is introduced.

One side cover groove 716 into which one end of the uneven heat dissipation member 710 is introduced is formed in the one side cover member 150, and the other end of the uneven heat dissipation member 710 is introduced into the other side cover member 160. The other side cover groove 718 is formed.

One side of the concavo-convex heat dissipation member 710 is introduced into the one side concavo-convex inlet groove 712, the other side of the concavo-convex heat dissipation member 710 is introduced into the other concavo-convex inlet groove 714, the concavo-convex heat dissipation member ( When one end of the 710) is inserted into the one side cover groove 716, and the other end of the uneven heat dissipation member 710 is introduced into the other side cover groove 718, the lower portion of the housing 130 is provided by the uneven heat dissipation member 710. Is closed.

The uneven heat dissipation member 710 is made of a metal material and has a high thermal conductivity.

The concave portion formed on the upper portion of the uneven heat dissipation member 710 surrounds the lower portion of the heat dissipation fin part 116, so that the upper surface of the horizontal heat dissipation member 510 formed in the fourth embodiment is on the lower surface of the heat dissipation fin part 116. The area in contact with the heat dissipation fin part 116 in the seventh embodiment is increased than the contact form, so that more heat generated from the heat dissipation fin part 116 is discharged to the outside of the housing 130 through the uneven heat dissipation member 710. .

In addition, a plurality of heat dissipation conducting fins 730 are formed in the convex portion formed under the uneven heat dissipation member 710 in the width direction of the uneven heat dissipation member 710.

The plurality of heat dissipation conducting fins 730 are arranged side by side to increase the contact area with water to quickly discharge high heat transmitted from the top of the uneven heat dissipation member 710.

The present invention has the effect of quickly dissipating high-temperature heat transmitted from the heat dissipation fin unit 116 through the seventh embodiment of the underwater lighting device 100.

As described above, the embodiments of the present invention have been described, but on the basis of this, if a person having ordinary skill in the relevant technical field does not deviate from the essential technical idea of the present invention described in the claims, the addition of components, The present invention may be variously modified and changed by changes, deletions, additions, etc., which are also included within the scope of the present invention.

100: underwater lighting device 110: optical module unit
112: LED 114: the substrate portion
116: heat dissipation fin part 118: uneven line
116-1: One side extension part 116-2: The other side extension part
130: housing portion 150: one side cover member
152: one side groove 160: the other side cover member
162: the other groove 170: one side support member
180: the other side support member 190: power supply
222: driven gear 224: drive gear
310: first through hole 311: second through hole
312: connecting rod 314: thread
410: incision 430: packing member

Claims (5)

The optical module unit 110 in which a plurality of light sources are disposed in the longitudinal direction,
The housing unit 130 is formed to surround the periphery of the optical module unit 110,
One side cover member 150 and the other side cover member 160 coupled to both side surfaces of the housing portion 130,
Power supply unit 190 for transmitting power to the optical module unit 110 and
It includes a plurality of heat dissipation fins 116 formed at regular intervals under the optical module unit 110,
When the light emitted from the optical module unit 110 is transmitted to the outside through the housing unit 130 by the power transmitted from the power supply unit 190, high heat is generated in the optical module unit 110, and the heat radiation fin unit 116 is generated. Receives the high heat and discharges it to the surroundings,
A portion of the heat dissipation fin portion 116 is extended to form the heat dissipation fin extension portions 116-1 and 116-2,
The housing portion 130 is formed with through holes 132 and 134 through which the radiating fin extension portions 116-1 and 116-2 penetrate,
Packing portions 136 and 138 are formed between the radiating fin extension portions 116-1 and 116-2 and the through holes 132 and 134,
The ends of the radiating fin extension portions 116-1 and 116-2 are exposed to the outside of the housing 130 through the through holes 132 and 134,
The housing 130 is wrapped around only the upper and longitudinal sides of the optical module unit 110, and is formed in an open state below the optical module unit 110,
A heat dissipation member 510 that is in contact with the heat dissipation fin part 116 is formed on the opened part of the housing part 130 while blocking the open part of the housing part 130.
A lower radiating portion 530 in the form of a radiating fin is formed under the radiating member 510,
An underwater lighting device, characterized in that a heat radiation rod portion 610 is formed between the lower heat dissipation portion 530 and an adjacent lower heat dissipation portion.
The method according to claim 1,
The radiating fin portion 116 is an underwater lighting device, characterized in that the uneven line 118 is formed on the surface.
The method according to claim 2,
The one side cover member 150 and the other side cover member 160 are formed of a metal material having high thermal conductivity, so that the one side cover member 150 is in close contact with one side of the optical module unit 110, and the other side cover member 160 is light. Underwater lighting device characterized in that it is in close contact with the other side of the module unit (110).
delete The method according to any one of claims 1 to 3,
An underwater lighting device, characterized in that a concave portion is formed to surround the lower portion of the radiating fin portion 116 on the upper portion of the radiating member 510.

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