KR101958950B1 - High output floodlight having water-cooled system - Google Patents

Abstract

The present invention relates to a water-cooled high-output light-emitting lamp system, and more particularly, to a light-emitting lamp system in which a plurality of light-emitting lamps are installed, in which a fluid supplied from a pump circulates a plurality of light- And a heat-radiating high-power light-emitting lamp system which improves the cooling efficiency by forming a space of a heat sink provided under the LED panel inside the light-emitting lamp in accordance with the arrangement of the LEDs.
The present invention is characterized in that a plurality of heaters and a plurality of LEDs are mounted on the bottom portion where the pump is installed, the column portion provided on the upper surface of the bottom portion, the mounting portion provided on the upper end of the column portion, And a circulation part for connecting the pump and the light-emitting lamp to each other and circulating the fluid through the plurality of light-emitting lamps, It is essential.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water-

The present invention relates to a water-cooled high-output light-emitting lamp system, and more particularly, to a light-emitting lamp system in which a plurality of light-emitting lamps are provided, in which a fluid supplied from a pump circulates a plurality of light- And a heat-radiating high-power light-emitting lamp system which improves the cooling efficiency by forming a space of a heat sink provided under the LED panel inside the light-emitting lamp in accordance with the arrangement of the LEDs.

In general, a light emitting diode (hereinafter referred to as LED) has advantages such as low power consumption, long lifetime, fast processing speed and long life, and is recently used in traffic lights, security lamps, floodlights and the like.

However, there is a problem in that a floodlight using such an LED is deteriorated in its characteristics due to heat generated in the LED, or thermal damage is caused to the peripheral devices, thereby frequently causing faults.

In order to prevent such a problem, a conventional method of mounting a heat sink made of a material having a high thermal conductivity, a method of facilitating heat dissipation by providing space around the LED, or a method of cooling an LED using a fan Were used.

However, when such a system is used, the size of the system must be increased due to the space and the additional device, which are required to have a floodlight, so that the weight of the system must be increased accordingly.

In the case where there is a need to arrange a plurality of floodlights, for example, in a surgical operation for medical purposes, or in an outdoor activity such as a tunnel light or nighttime, It is difficult to apply it due to a flood light, and after the installation, troubles such as frequent occurrence of troubles and LED replacement work are not enough.

KR 101560206 B1 KR 101529546 B1

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a system for cooling LEDs provided in a plurality of projected lights or the like by circulating fluids, Which is designed to improve the cooling efficiency by forming a lower structure which is a flow path of the cooling water passage.

The objects of the present invention are not limited to the above-mentioned objects, and other objects not mentioned can be clearly understood from the following description.

In order to attain the above object, the water-cooled high-power floodlighting system according to the present invention comprises a bottom provided with a pump, a column provided on the upper surface of the bottom portion, a mounting portion provided on the upper end of the column portion, A light pipe having an LED panel having a heat sink and a plurality of LEDs mounted thereon, and a heat sink connected to the pump and the heat sink, And a circulation unit for circulating the fluid through the plurality of light sources and allowing the fluid to flow into or out of the heat sink, wherein the heat sink is a hollow structure attached to a lower portion of the LED panel, In the heat sink, a first space portion contacting the portion where the LED is disposed is formed on the upper surface of the LED panel, and the LED is not disposed on the upper surface of the LED panel The first space portion is formed with a larger cross-sectional area perpendicular to the flow direction of the fluid than the second space portion, so that the fluid flowing through the first space portion is divided into the second space portion The flow rate is slower than that of the fluid to be flowed, so that the amount of heat transferred to the LED is increased, so that the cooling efficiency is increased.

The present invention with the above-described configuration can be expected to have the following effects.

As a result of the water-cooled cooling applied by the fluid supplied from the lower part, the light transmission light is reduced in size and weight, and a plurality of light beams can be installed on the upper part of a support such as a vertical column.

By applying water-cooled cooling that uses LEDs to cool the fluid, the cooling efficiency is increased compared to the commonly used air-cooled type. In the lower part of the LED, a feature characterized by being capable of both water-cooled cooling and air-cooling is applied, and the upper part of the LED is provided with a space for air cooling so that a higher cooling effect can be obtained. This is because the space for air cooling can be minimized by applying the water cooling cooling so that it can be implemented without increasing the size and weight of the flood light.

Due to the increase of the cooling effect, the frequency of occurrence of failure of the peripheral device due to the heat emitted from the LED is reduced, and the replacement cycle of the LED becomes longer, so that the cost of parts consumed and the number of times of replacement work can be reduced.

In addition, by providing a sensing unit for sensing the ambient temperature and a control unit for controlling the operation of the pump by processing the sensing information, it is determined whether or not the fluid is supplied according to the ambient temperature to control the operation of the unnecessary system, It is possible to minimize the increase in power consumption and power consumption.

1 is an overall configuration diagram of a water-cooled high-power light projection system according to an embodiment of the present invention.
2 is a cross-sectional view of a light projector according to an embodiment of the present invention.
3 is a configuration diagram of an LED panel and a heat sink according to an embodiment of the present invention.

Hereinafter, a water-cooled high-power light projection system according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2 is a cross-sectional view of a light source 400 according to an embodiment of the present invention, and Fig. 3 is a cross-sectional view of an embodiment of the present invention. FIG. 4 is a configuration diagram of the LED panel 430 and the heat sink 450 according to FIG.

As shown in FIG. 1, a water-cooled high-power light projection system according to a preferred embodiment of the present invention includes a floor 100 on which a pump 110 is installed, a column 200 installed on an upper surface of the floor 100, An LED panel 430 in which a plurality of LEDs are installed in the mounting part 300 and a heat sink 450 and a plurality of LEDs 410 are attached to the mounting part 300; And a plurality of light emitting lamps 400 installed in the form of a flow path connecting the pump 110 and the light emitting lamp 400 and having a fluid flow therein, And a circulation unit 500 for circulating the fluid through the circulation unit 500.

First, the bottom part 100 will be described.

The bottom part 100 is a part abutting the ground, and the other components of the present invention are installed on and supported by the upper part of the bottom part 100.

The bottom part 100 is formed in a wide plate shape, and may have any shape such as a square or a circle. However, the width of the bottom part 100 should be such that the lateral stability of the present invention can be structurally sufficiently ensured according to the height of the column part 200 and the size of the mounting part 300, which will be described later.

The bottom portion 100 is provided with a pump 110 which is a device for transporting fluid of a liquid or a gas through a pipe by a pressure action or for feeding a fluid in a low pressure container through a pipe into a high pressure container.

The pump 110 causes the fluid supplied from the outside to be transported upward by the light transmitter 400 provided in the mounting part 300 to be described later and is continuously supplied to the inside of the circulation part 500 to be described later Provide hydraulic pressure.

Additionally, the bottom part 100 may include a sensing part 600 for sensing the temperature of the surroundings of the present invention and a control part 700 for controlling the operation of the pump 110 to receive sensed information . Accordingly, when the outside temperature is very low, it is possible to satisfy the desired cooling effect even if only the air-cooling type is used, so that the operation of the pump 110 is suppressed. In the case where the external temperature is high, The operation of the unnecessary pump 110 can be minimized.

However, the sensing unit 600 and the control unit 700 can be installed anywhere other than the bottom 100 due to various reasons such as user's convenience of operation, accessibility, installation environment, and the like.

Next, the pillar portion 200 will be described.

The columnar part 200 is provided on the upper surface of the bottom part 100 and functions to provide a height to the mounting part 300 and a plurality of the floodlights 400 to be described later.

It is preferable that the columnar part 200 is formed in the center of the bottom part 100 for structural stability and has a hollow cylindrical shape.

A plurality of light emitting lamps 400 are installed on the mounting part 300 and a plurality of light emitting lamps 400 connected to the light emitting lamp 400 from an external power supply source are installed on the upper part of the column part 200. [ The electric wire may be disposed inside the pillar 200. A circulation part 500, which will be described later, which is a flow path for connecting the fluid supplied from the pump 110 installed at the lower part to the floodlight 400 at the upper part, may also be disposed inside the pillar part 200.

Next, the mounting unit 300 will be described.

The mounting part 300 is provided on the upper part of the column part 200 and serves to provide a supporting base to which the floodlight 400 can be attached. The size of the mounting part 300 is determined according to the number of the light emitting devices 400 attached to the mounting part 300 so that the width of the mounting part 300, the height of the column part 200, and the width of the bottom part 100 Are interrelated to provide structural stability.

The mounting portion 300 may be formed in any shape, such as a square or a circle. The mounting portion 300 may be formed in a three-dimensional configuration so that light emitted from the light source 400 may be provided at various angles to minimize shadows, Various variations are possible.

Next, the light-emitting lamp 400 will be described.

The light transmitter 400 includes a light transmitter 400, an LED panel 430 with an LED, a heat sink 450, a reflector 470, and a radiator fin 490 in a light- Respectively. The floodlight 400 is a known technique and will not be described in detail, but components having special technical characteristics such as the LED panel 430 and the heat sink 450 will be mainly described.

A plurality of LEDs 410 are arranged on the upper surface of the LED panel 430, and the arrangement of the LEDs 410 is concentrated on one side of the upper surface of the LED panel 430. The LED panel 430 is installed under the light-transmitting lamp body A so as to face the upper portion of the light-emitting lamp body A.

A reflector 470 is installed at one end of the LED panel 430 on which the LED 410 is disposed to form an angle of 70 ° to 80 ° with the upper surface of the LED panel 430. The light emitted from the LED 410 is reflected by the reflection plate 470 and exits to the front side of the light-emitting body A.

A heat sink 450 is provided on the lower surface of the LED panel 430. The heat sink 450 receives heat generated by the LED 410 and dissipates heat to the outside, and may be made of aluminum, copper, copper, or the like having high thermal conductivity.

The heat sink 450 is a hollow structure that is configured to abut the heat sink 450 with the same area as the lower surface of the LED panel 430. The heat sink 450 is connected to the circulation unit 500 to be described later, The fluid flows into the heat sink 450 and the fluid absorbing the heat of the LED 410 flows out through the circulation unit 500 again.

A first partition 451 is formed in the heat sink 450 in a direction parallel to the flow direction of the fluid and a first space portion 450a which is a portion contacting the portion where the LED 410 is disposed on the upper surface of the LED panel 430 And a second space portion 450b on the upper surface of the LED panel 430, which is in contact with a portion where the LED 410 is not disposed.

The first space portion 450a is relatively larger than the second space portion 450b. More specifically, the second space 450b is further provided with a second partition 452 in a direction parallel to the flow direction of the fluid, so that the cross-sectional area perpendicular to the flow direction of the fluid is larger than the first space 450a. .

Since the first space portion 450a has a larger cross-sectional area perpendicular to the flow direction of the fluid than the second space portion 450b, the cross-sectional area perpendicular to the flow direction of the fluid at a constant flow rate is inversely proportional to the flow rate The flow rate of the fluid flowing through the first space portion 450a is slower than the flow rate of the fluid flowing through the second space portion 450b.

Accordingly, since the fluid passing through the first space portion 450a has a relatively slow flow rate, the heat transfer amount generated by the LED 410 disposed on the upper surface of the first space portion 450a is further increased, do.

The fluid passing through the second space portion 450b has a relatively fast flow rate and flows quickly inside the heat sink 450. [ In addition, as the flow rate of the heat released from the heat sink 450 increases, the fluid can also act as a propelling force to flow the fluid within the circulation unit 500, which will be described later.

A plurality of protrusions 453 are formed in the heat sink 450 to maximize a cross-sectional area of a body of the heat sink 450, which receives heat, in contact with the fluid inside the heat sink 450 . The right and left side surfaces of the heat sink 450 through which the fluid flows are sealed by the waterproof silicone 454 and the heat sink stopper 455 to prevent leakage of water.

A protruding portion 456 is formed under the first space portion 450a of the heat sink 450 and the protruding portion 456 is in contact with the radiating fin 490 provided on the rear surface of the light- The radiating fins 490 for radiating heat to the outside of the light emitting body A are formed in a plurality of protruding shapes in order to widen the contact area with the air, and thus the detailed description thereof will be omitted.

The heat generated from the LED 410 is cooled by the cooling of the water by the fluid flowing inside the heat sink 450 and the heat generated by the heat sink 450 is absorbed by the heat sink 450. [ The cooling water is transferred to the protruding portion 456 and the cooling fins 490 are brought into contact with the protruding portion 456 to perform air cooling cooling.

Finally, the circulation unit 500 will be described.

The circulation unit 500 is configured in the form of a flow path for the fluid to flow therein and is installed between the pump 110 and the light source 400 and between the light source 400 and the light source 400 And a plurality of light-emitting lamps 400 installed on the mounting part 300 are all passed through.

The fluid ascending from the pump 110 flows into the heat sink 450 inside the first light source 400 by the circulation unit 500 connecting the pump 110 and the floodlight 400, When the fluid flowing in the heat sink 450 flows out of the first floodlight 400, the circulation part 500 installed between the floodlight 400 and the floodlight 400 can heat the inside of the second floodlight 400 And is circulated in all of the plurality of light-emitting lamps 400 installed in the sink 450.

The present invention is characterized in that a pump 110 is installed on a floor 100 for cooling a plurality of LEDs 410 inside a floodlight 400 installed at a high position by a column 200 and a mount 300 The fluid that is raised and supplied by the pump 110 is designed to be subjected to the water-cooled cooling by the circulation unit 500 while passing through all of the plurality of floodlights 400. Particularly, in order to maximize the efficiency of the circulating water-cooled cooling system, the shape of the heat sink 450 through which the fluid flows is formed in the first space part 450a and the second space part 450b, The cooling efficiency is increased, and the cooling is performed in parallel with the air cooling type cooling by the projecting portion 456.

The above-described embodiments are merely illustrative, and various modifications may be made by those skilled in the art without departing from the scope of the present invention.

Therefore, the true technical protection scope of the present invention should include not only the above embodiments but also various other modified embodiments according to the technical idea of the invention described in the following claims.

100:
110: pump
200:
300:
400: Floodlight
410: LED
430: LED panel
450: Heatsink
450a: a first space portion
450b: the second space portion
451: first partition
452: second partition
453: protrusion projection
454: Waterproof silicone
455: Heatsink plug
456:
470: reflector
490: heat sink fin
500: circulation part
600:
700:
A: Floodlight body

Claims (5)

A bottom on which the pump is installed;
A column portion provided on an upper surface of the bottom portion;
A mounting portion provided at an upper end of the column portion;
A plurality of LED lamps having a heat sink and a plurality of LEDs mounted on the mounting portion; And
The heat sink is connected to the pump and the heat sink provided inside the light source, and is configured in the form of a flow path through which the fluid flows. The heat sink circulates the fluid through the plurality of light- And a circulation unit for causing the liquid to flow in or out,
Wherein the heat sink is a hollow structure attached to a lower portion of the LED panel. The heat sink includes a first space formed on an upper surface of the LED panel and abutting a portion where the LED is disposed, And the first space portion has a larger cross-sectional area perpendicular to the flow direction of the fluid than the second space portion, so that the fluid flowing in the first space portion is divided into the first space portion and the second space portion, 2 < / RTI > space, the flow rate is slower than that of the fluid flowing in the space, and the amount of heat transferred to the LED is increased, thereby increasing the cooling efficiency. delete delete The method according to claim 1,
A sensing unit attached to the bottom and sensing ambient temperature; And
Further comprising a control unit for receiving information sensed by the sensing unit and controlling whether the pump is operated or not. The method according to claim 1,
Wherein the heat sink is formed with a protrusion at a lower portion of the heat sink facing the portion where the LED is disposed, and the protrusion is in contact with the rear heat dissipation fin.

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