KR101264401B1 - Street lamp apparatus having efficient heat emission property - Google Patents

Abstract

PURPOSE: A street lamp apparatus having an efficient heat dissipation property is provided to lengthen the lifetime of an LED by blocking a heat transmission path in daytime using a heat transmission member. CONSTITUTION: A housing includes a receiving space inside. A light emitting unit(400) is combined in the lower part of the housing. A heat dissipation unit(300) is installed in the receiving space. A drive unit(500) drives the heat dissipation unit by driving a drive motor. A control unit controls the driving of the drive unit.

Description

Street lamp apparatus having efficient heat emission property

The present invention relates to a street lamp device having an efficient heat dissipation characteristics, and more particularly to a street lamp device that can perform heat radiation efficiently by blocking the transfer of radiant heat by the sun to the light emitting unit during the day.

Recently, street lamps using light emitting diodes (LEDs) have been developed. The street lamps using LEDs have a significantly lower power consumption than the street lamps using sodium or mercury bulbs, and are more than the same as those of street lamps. In addition to having brightness, its lifespan is many times longer, resulting in significantly lower management costs and increasing usage.

Such advantages of high brightness, low power consumption and long lifespan are widely used in various fields such as indoor lighting, decorative lighting, and vehicle lighting in addition to streetlight devices.

High brightness LEDs, however, have the disadvantage that they are susceptible to heat, despite these advantages. In particular, in the case of a street lamp device requiring high brightness, since a plurality of high-power LEDs must be used, if the high heat generated by long-term use cannot be effectively discharged, a low heat resistance LED is damaged by heat.

In order to solve this problem, various types of street light devices have been proposed that can efficiently radiate heat generated from LEDs by applying heat sinks to the street light devices.
For example, in Korean Patent Publication No. 0934501, the heat dissipation device of the present invention is installed on an upper portion of a heat source generating heat, and a base plate receiving heat generated from the heat source, and a plurality of heat dissipation fins are stacked on the base plate. And a heat dissipation fin unit formed therein, a plurality of heat transfer members for supporting the heat dissipation fin unit and dissipating heat transferred from the base plate to the heat dissipation fin unit, and air formed in the heat dissipation fin unit and heated from the bottom of the heat dissipation fin unit. Disclosed is a heat dissipation device having ventilation means for venting air. According to this configuration, by using the heat transfer member to quickly discharge the high-temperature heat generated from the light emitting diode module to the heat radiation fins to improve the cooling efficiency, by forming a heat flow section through which the air heated from the bottom flows upward in the heat radiation fin unit The circulation of air can further improve the cooling efficiency.
In addition, in Korean Patent Publication No. 1095944, the streetlight mechanism is composed of an upper case, a lower case, and an LED module unit to form a simple and simple structure to increase workability and productivity, and to provide air distribution holes formed in the upper case and the lower case. Through natural convection of internal and external air, heat dissipation is efficiently achieved.

However, the heat transfer member or the heat sink applied to the conventional street lamp device can efficiently radiate heat generated from the LED or the circuit components to the outside, but the radiant heat received from the sun is rather led to the LED during the day when the street lamp is not lit. There is a problem that the transmission has a great impact on the life of the LED.

Accordingly, it is an object of the present invention to provide a streetlight device that blocks the heat transfer path during the day so that external radiant heat is not transmitted to the light emitting unit.

Another object of the present invention is to provide a street lamp device having waterproofness so that water does not penetrate from the outside while having efficient heat dissipation by air convection.

The above object, the housing is provided with a storage space therein; A light emitting unit coupled to a lower portion of the housing; A heat dissipation unit installed in the storage space and having one side fixed to the light emitting unit and the other side being in contact with or separated from the housing; And a driving unit for driving the heat dissipation unit, wherein the heat dissipation unit contacts the housing to transfer heat generated in the light emitting unit to the housing, or a path in which heat applied to the housing from the outside is conducted away from the housing. It is achieved by a street lamp device having an efficient heat dissipation characteristics, characterized in that the blocking.

Preferably, the heat dissipation unit, the support plate for thermally coupling with the light emitting unit; A plurality of heat transfer members having the other end coupled to the support plate and capable of being folded or bent; And one end pivotably coupled to the housing, and the other end coupled to the drive unit, and one end of the heat transfer member is coupled to the heat sink.

Preferably, the drive unit, a drive motor fixed to the housing; And a cam member coupled to the rotation shaft of the drive motor, and the other end of the heat sink moves up and down in contact with the cam member.

Preferably, the housing includes: an upper housing having a ring-shaped rib protruding from the surface thereof, a groove formed along an outer side of the rib, and an air passage slot formed inside the rib; And a lower housing coupled to the upper housing and to which the light emitting unit is coupled.

Preferably, in the lower housing, a plurality of ribs protrude from a surface portion corresponding to a portion to which the light emitting unit is coupled, and the heat dissipation unit is coupled to the surface portion.

Preferably, the cover further comprises a cover coupled to the upper housing such that a gap is formed between the surface of the upper housing along an edge, and air is convection through the receiving space, the air passage slot, and the gap.

According to the above structure, it is possible to extend the life of the LED by blocking the heat transfer path during the day using a heat transfer member installed to be movable therein so that external radiant heat is not transmitted to the light emitting unit.

In addition, heat dissipation is improved by convection of air through a passage connecting the inside and the outside of the housing.

In addition, while providing efficient heat dissipation by air convection, water does not penetrate from the outside structurally.

1 is an exploded perspective view illustrating a streetlight device according to an exemplary embodiment of the present invention.
2 is a partial cutaway perspective view of a streetlight device according to an exemplary embodiment of the present invention.
3 is a partial cutaway perspective view of the streetlight apparatus viewed from another angle.
4 is a cross-sectional view taken along the side.

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

1 is an exploded perspective view of a streetlight device according to an embodiment of the present invention, Figure 2 is a partial cutaway perspective view of a streetlight device according to an embodiment of the present invention, Figure 3 is a partial cutaway perspective view of the streetlight device from another angle 4 is a cross-sectional view taken along the side.

The street lamp device according to the present invention includes a housing 100 having an accommodation space 102 therein, a light emitting unit 400 coupled to a lower portion of the housing 100, and installed in the storage space 102 and one side of the light emitting unit 400. The heat dissipation unit 300, and the heat dissipation unit 300 to connect or block the heat transfer path between the light emitting unit 400 and the housing 100 by being fixed in contact with the other side and selectively contacting the housing 100. It includes a drive unit (500).

Hereinafter, each part of a streetlight device is demonstrated in detail.

housing (100)

The housing 100 may be made of an aluminum material, and the upper housing 110 and the lower housing 120 are coupled to each other, and a storage space 102 is formed therein by the coupling.

The housing 100 accommodates the heat dissipation unit 300 and the driving unit 500 and the necks 110a and 120a which are connected to a pillar (not shown) installed on the ground in addition to a part serving to support the light emitting unit 400. Also integrally provided.

A plurality of ring-shaped ribs 112 and 114 protrude from the surface of the upper housing 110, and grooves 116 are formed along the outer side of the outermost rib 112. According to this structure, the water flowing through the cover 600 to be described later is blocked by the rib 112 and flows along the groove 116 to be discharged.

In addition, in the upper housing 110, a plurality of air passage slots 118 are formed inside the ribs 112 and used as a passage through which air flows between the storage space 102 and the atmosphere.

The lower housing 120 may be screwed through the upper housing 110 and, for example, the boss 122, and the printed circuit board 410 of the light emitting unit 400 is coupled to the rear housing 120.

Preferably, in the lower housing 120, a plurality of ribs 125 protrude from opposite surfaces of the contact surface 124 to which the printed circuit board 410 is coupled, and a support plate of the heat dissipation unit 300 on the ribs 125. 330 combines.

Heat dissipation unit 300

The heat dissipation unit 300 is composed of a heat dissipation plate 310, heat transfer members 320, 322, 324, and a support plate 330.

The heat sink 310 has a plate shape, and flanges 312 and 314 are formed at both ends in the longitudinal direction, and the flange 312 is fixed to the lower housing 120. The flange 312 is lowered to allow the heat sink 310 to be rotatable. It is fixed to the housing 120.

To this end, as shown in Figure 1, using a screw 313 can be loosely fixed, or a spring acting as a pivot can be applied. In this embodiment, the screw 313 is loosely fixed and rotated by the weight of the heat sink 310.

A pair of contact protrusions 316 and 318 protrude from the other flange 314 of the heat sink 310 to serve as a trigger for turning on and off the limit switches 530 and 540 described later.

In addition, the flange 314 maintains contact with the cam member 550 of the driving unit 500 by the weight of the heat sink 310, and as will be described later, the heat sink 310 is rotated in accordance with the rotation of the cam member 550. Rotating around the fixed end of the flange 112, the upper housing 110 is contacted or separated.

One end of the plurality of heat transfer members 320, 322, and 324 is fixed to the rear surface of the heat sink 310. The heat transfer members 320, 322, and 324 literally transfer heat, and in this embodiment, serve to thermally connect the support plate 330 and the heat sink 310.

The heat transfer members 320, 322, and 324 may have a folding structure or a bending structure as shown in FIG. 1, and it is important to unfold or fold according to the rotation of the heat sink 310.

The other ends of the heat transfer members 320, 322, and 324 are fixed to the support plate 330, and the support plate 330 is placed on the rib 125 formed on the contact surface 124 of the lower housing 120 and the lower housing 120. Combine with

Light emitting unit 400

The light emitting unit 400 is a part that emits light and accommodates and protects a printed circuit board 410 and a printed circuit board 410 on which a high brightness LED (not shown) and a plurality of electronic components are mounted. 420).

The window 420 is coupled to the rear surface of the lower housing 120, and the printed circuit board 410 is in thermal contact with the contact surface 124 of the lower housing 120.

Drive unit 500

The driving unit 500 drives the heat dissipation unit 300 so that the heat dissipation plate 310 is in contact with or separated from the upper housing 110, the driving motor 520, the cam member 550, and the pair of switches 530. 540). These are all installed on the support bracket 510 protruding from the lower housing 120.

The cam member 550 is fitted to the rotation shaft of the driving motor 520, and the pair of limit switches 530 and 540 correspond to the contact protrusions 316 and 318 protruding from the flange 314 of the heat sink 310. Spaced apart and fixed to the support bracket 510. Thus, as described above, the contact protrusions 316 and 318 operate by contact-pressing the limit switches 530 and 540, respectively.

As will be described later, by the contact protrusions 316 and 318 contact-pressing the limit switches 530 and 540, respectively, the limit switches 530 and 540 are turned on / off and the driving of the driving motor 520 is turned on / off accordingly. do.

It is also possible to apply a configuration different from this embodiment. For example, an air pump is applied instead of the driving motor 520, air is supplied from the air pump instead of the cam member 550, or air is drawn out by the air pump, and the flange 314 of the heat sink 310 is applied. An air bag that couples to can be applied. Therefore, when air is supplied to the air bag by the air pump, the air bag swells, and as a result, the heat sink 310 moves upward, and conversely, when the air of the air bag is taken out, the heat sink 310 moves downward.

Cover (600)

The cover 600 is coupled to the surface of the upper housing 110 in a dome shape, so that a gap of about 1 mm to 5 mm is formed between the surfaces of the upper housing 110 along the edge.

The cover 600 is screwed with the upper housing 110 through the boss 610 protruding from the inner surface to provide a space therein to provide a space in which air can stay.

Control

Although not separately displayed, the controller receives the on / off signals from the limit switches 530 and 540 to control the driving of the driving motor 520. In addition, it may be connected to the illumination sensor to control the start of the driving motor 520 by distinguishing between day and night.

Hereinafter, the operation of the street lamp device having the above structure will be described.

First, the operation at night will be described.

When the control unit receives the operation signal by the operator's operation, or when receiving the night detection signal from the illumination sensor, it is determined as a signal to open the heat transfer members (320, 322, 324).

Accordingly, the drive motor 520 is rotated by the command of the controller, and the cam member 550 coupled to the rotation shaft of the drive motor 520 rotates to contact the cam member 550 in the long radial direction of the heat sink 310. Push up the flange 314.

Since the other flange 312 of the heat sink 310 is fixed, the heat sink 310 is rotated counterclockwise around the flange 312, and thus, one end of the heat sink 310 is fixed to the rear surface of the heat sink 310. Members 320, 322, 324 are unfolded.

As shown in FIG. 4, the heat sink 310 continuously rotates and contacts the rear surface of the upper housing 110, wherein the contact protrusion 316 protruding from the flange 314 of the heat sink 310 is the limit switch 530. When pressed, the switch signal is transmitted to the controller, and the controller stops the driving motor 520 based on the switch signal.

Therefore, the conductive heat generated from the printed circuit board 410 is discharged to the outside through the support plate 330 of the heat dissipation unit 300-heat transfer members 320, 322, 324-heat dissipation plate 310-upper housing 110 do. In addition, radiant heat generated from the high-brightness LED is mixed with air in the receiving space 102 to pass through the air passage slot 118 of the upper housing 110 and between the surface of the upper housing 110 and the edge of the cover 600. It is released to the outside through the gap 101 formed in the.

On the other hand, when receiving an operation signal by the operator's operation, or when receiving a weekly detection signal from the illumination sensor, the control unit determines that the signal to fold the heat transfer member (320, 322, 324).

Accordingly, the drive motor 520 is rotated again by the command of the controller, the cam member 550 coupled to the rotation axis of the drive motor 520 is rotated while the flange of the heat sink 310 on the cam member 550 in a short radial direction The surface of the heat sink 310 is separated from the rear surface of the upper housing 110 by rotating the heat sink 310 clockwise by the weight of the heat sink 310 so that the 314 is in contact with each other. In addition, the heat transfer members 320, 322, and 324 having one end fixed to the rear surface of the heat sink 310 are folded in response to the rotation of the heat sink 310.

While the heat sink 310 continues to rotate, the contact protrusion 318 protruding from the flange 314 of the heat sink 310 presses the limit switch 540, the switch signal is transmitted to the controller, and the controller is driven based on the switch signal. Stop the motor 520.

As a result, since the heat dissipation plate 310 is physically separated from the upper housing 110, solar heat transmitted to the upper housing 110 may be blocked from being transferred to the printed circuit board through the heat dissipation plate 310. .

Even though the heat sink 310 is physically separated from the upper housing 110, the air in the storage space 102 is not exposed to the air passing slot 118 of the upper housing 110 and the surface of the upper housing 110 and the cover 600. Convection to the outside through the gap 101 formed between the edges.

In the above description, the embodiment of the present invention has been described, but various changes can be made at the level of those skilled in the art. Therefore, the scope of the present invention should not be construed as being limited to the above embodiment, but should be interpreted by the claims described below.

100: Housing
110: upper housing
120: lower housing
124: support plate
125: rib
300: heat dissipation unit
310: heat sink
312, 314: flange
320, 322, 324: heat transfer member
400: light emitting unit
410: printed circuit board
420: Windows
500: drive unit
510: bracket
520: drive motor
530, 540: limit switch
550: cam member
600: cover

Claims (6)

A housing having an accommodation space therein;
A light emitting unit fixed to the lower housing by coupling;
A heat dissipation unit installed in the storage space and having one side fixed to the light emitting unit and the other side being in contact with or separated from the housing;
A drive unit fixed to the housing, the drive unit driving the heat dissipation unit by driving the drive motor; And
A control unit for controlling the driving of the drive unit,
By the driving of the driving unit under the control of the control unit, the heat dissipation unit is in contact with the housing to transfer heat generated in the light emitting unit to the housing or heat applied to the housing from the outside away from the housing is the light emitting unit Street light device having an efficient heat dissipation characteristics, characterized in that for blocking the path conducted to. The method according to claim 1,
The heat-
A support plate thermally coupled to the light emitting unit;
A plurality of heat transfer members coupled with the other end to the support plate and capable of being folded or bent; And
One end is pivotally coupled to the housing, the other end includes a heat sink coupled to the drive unit,
One end of the heat transfer member is a street lamp device having an efficient heat dissipation characteristics, characterized in that coupled to the heat sink. The method according to claim 2,
The drive unit includes a cam member coupled to the rotation shaft of the drive motor,
The other end of the heat sink is a street lamp device having an efficient heat dissipation characteristics, characterized in that the cam member moves up and down. The method according to claim 1,
The housing includes:
An upper housing in which a ring-shaped rib protrudes from a surface thereof, a groove is formed along an outer side of the rib, and an air passage slot is formed inside the rib; And
And a lower housing coupled to the upper housing and to which the light emitting unit is coupled to a rear surface thereof. The method of claim 4,
In the lower housing, a plurality of ribs protrude from the surface portion corresponding to the portion to which the light emitting unit is coupled,
Street light apparatus having an efficient heat dissipation, characterized in that the heat dissipation unit is coupled to the surface portion. The method of claim 4,
A cover coupled over the upper housing such that a gap is formed between the surface of the upper housing along an edge;
Efficient heat dissipation, characterized in that the air convection through the path leading to the storage space, the air passage slot and the gap.

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