KR100396783B1 - Device cooling electro-communication apparatus - Google Patents

Abstract

The present invention relates to a cooling device for communication equipment. In particular, in the case of communication equipment such as an outdoor base station, high heat generating parts having a high heat generation density operating in an enclosed space are concentrated in a certain portion, and heat generated from the high heat generating parts is cooled. The cooling unit of the electronic communication equipment for cooling by forming a door portion having a cooling means for cooling to the outside of the high heat generating parts.

Description

Cooling device for electronic communication equipment {DEVICE COOLING ELECTRO-COMMUNICATION APPARATUS}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electronic communication device. In particular, a cooling device of an electronic communication device that concentrates and cools parts having high heat density, and in the case of an outdoor base station, collects high heat generating parts operated in a closed space in a specific part and concentrates them. It relates to a cooling device for electronic communication equipment for cooling.

In general, the cooling device of the electronic communication equipment is a device that cools the heat generated in the heat generating unit and lowers it to a constant temperature, and emits heat to the atmosphere at room temperature.

As the heat dissipation method, convection and conduction are mainly used as heat transfer methods for dissipating heat generated from electronic communication equipment among three types of heat transfer methods: convection, conduction and radiation.

The method using conduction attaches a heat sink with high thermal conductivity to the heat generating unit so that it has a temperature gradient inside the heat sink to easily transfer heat from the high side to the low side, and convection allows fluid to flow around the heat generating unit. There is a forced convection method in which the fluid is forced to circulate by using a blower or a motor so that the fluid can be contacted with more fluid around the heat generating element and the natural convection flowing in the density difference generated by the heat obtained from the heat generating part.

Referring to the cooling apparatus of the prior art electronic communication equipment according to the drawings shown in Figures 1 and 2, Figure 1 is a partial perspective view of a communication device having a conventional external heat radiation fin, Figure 2 is a conventional internal heat radiation fin and an external heat radiation fin It is a partial perspective view of the communication equipment having.

As shown in FIG. 1, the outdoor base station includes one surface of the main body casing 1 as a heat dissipation plate 2 of a square plate having good thermal conductivity, and a plurality of high heat generating parts 3 are formed on an inner surface of the heat dissipation plate 2. Position), and the heat dissipation fins 4 of the rectangular thin plate are continuously attached to the outer surface of the heat dissipation plate 2 at a predetermined interval.

The heat generated from the high heat generating component 3 is conducted to the heat dissipation plate 2 to which the high heat generating component 3 is attached and supported, and the heat conducted to the heat dissipating plate 2 is conducted to the heat dissipation fin 4. Heat conducted to (4) is cooled by emitting heat to the outside air through heat transfer by convection in contact with the outside air at room temperature in contact with the surface area of the heat dissipation fin (4).

In addition, in order to increase the cooling efficiency of the outdoor base station illustrated in FIG. 1, as illustrated in FIG. 2, the outdoor base station includes one surface of the main body casing 11 as a heat sink 12 having high thermal conductivity. External heat radiation fins 15 continuously connecting a plurality of rectangular thin plates to the outer surface of the inner surface 12, internal heat radiation fins 14 continuously attached to the inner surface of the plurality of rectangular thin plates and a high heat generating component on the internal heat radiation fins 14. (13) is configured to attach.

The heat generated from the high heat generating component 13 is conducted to the internal heat dissipation fins 14 to which the high heat generating component 13 is attached and supported, and the internal heat dissipation fins 14 are partially in contact with the internal heat sink 14. Convection is released to the internal air inside the main body casing (11), and heat is conducted to the heat dissipation plate (12) supporting and supporting the internal heat dissipation fins (14).

In addition, the internal air that has received heat by convection of the internal air transfers heat back through the convection to the internal heat dissipation fin 14 that is not in contact with the high heat-generating component 13, and the internal heat dissipation fin 14 thus transferred is heat. To the heat sink 12, and the heat sink 12 conducts heat conducted from the internal heat sink fins 14 to the external heat sink fins 15, thereby convection on the outer surfaces of the heat sink 12 and the external heat sink fins 15. The heat is transferred to the outside by the external air to eventually release the heat generated in the high heat generating component 13 to the atmosphere to cool.

The conventional outdoor base station attaches the heat sinks 2 and 12 to the outside of the base station, and then attaches the high heat generating parts 3 and 13 to the heat sinks 2 and 12 to heat the high heat generating parts 3 and 13. It is composed of a heat sink (2) (12) integrated with the outdoor base station so as to discharge the heat generated in the outside through the heat sink (2) (12).

The prior art attaches the high heat generating components 3 and 13 to the heat sink 2 and 12 when the heat sink 2 and 12 is attached to the outdoor base station. .

In addition, due to the high heat generated by the high heat generating components (3) and (13), it is not possible to directly attach to the heat sink (2) (12). There is a problem that can not be applied when the maximum operating temperature of (not shown) is low, and if there are dense high heat generating parts 2 and 12, there is a problem that a separate fan or the like must be installed to cool the high heat generating parts. (2) There is a problem that the size of the base station is increased because a certain space is required to cool the (12).

In order to solve the above problems, the present invention is installed by combining a plurality of high heat generating component fixing bracket for fixing the concentrated high-heating components operating in a closed space to the outer surface of the body, and cover and seal the cooling after cooling By forming a door unit provided with a means to intensively cool the high heat-generating component, it has an object to improve the cooling efficiency.

1 is a partial cross-sectional perspective view of a communication device having a conventional external heat radiation fin,

2 is a partial cross-sectional perspective view of a communication device having a conventional internal heat radiation fin and an external heat radiation fin,

3 is a perspective view of the cooling device of the communication device of the present invention,

4 is an exploded perspective view of a main part of a cooling device of a communication device of the present invention;

5 is an exploded perspective view of a cooling device of a communication device of the present invention;

6 is a block diagram of an air distribution device of the cooling device of the communication equipment of the present invention.

* Description of the main parts of the drawings *

50. Main body 51. Coupling groove

52. Entrance 53. Fastening groove

54. Connector 60. Door part

61.Inlet 62. Cooling fan assembly

63. Cooling fan assembly housing 64. Inlet

65. Air duct 66. Air distributor

66a. Air distribution plate 66b. Rotating support shaft

66c. Fixing member 66d. Fixture

67. Air guide board 68. Air outlet

69. Air outlet 70. Fixed bracket

71. Heat sink 72. High heat generating parts

73. Heat sink 75. Socket

76. Fasteners 80. Hinge

According to the present invention in order to achieve the above object, a plurality of high heat-generating parts are concentrated and attached to one surface of the heat dissipation, and the fixing bracket to continuously attach the heat dissipation fins of a plurality of rectangular thin plates on the other surface; A main body portion formed at one outer side of a coupling groove for detachably coupling a plurality of the fixing brackets; A door portion having a cooling means for cooling the heat generated from the high heat generating parts attached to the fixed bracket is replicably coupled to one side of the main body portion; do.

Here, the cooling apparatus of the electronic communication device of the present invention will be described according to an embodiment shown in FIGS. 3 to 6 as follows.

Figure 3 is a perspective view of the cooling device of the electronic communication equipment of the present invention, Figure 4 is an exploded perspective view of the main portion of the main body of the cooling device of the electronic communication equipment of the present invention, Figure 5 is an exploded perspective view of the cooling device of the electronic communication equipment of the present invention. 6 is a block diagram of an air distributor of the cooling device of the electronic communication device of the present invention.

As shown in FIG. 3, the door-type outdoor base station covers a main body 50 for accommodating parts (not shown) necessary for communication with an electromagnetic plate (not shown) and one surface of the main body 50. It is composed of a door portion 60 is coupled to the hinge 80 so as to have a cooling means for cooling the heat generated in the main body portion 50.

As shown in FIG. 4, a plurality of late fixing brackets 70 are coupled to an outer surface of the main body part 50 to accommodate the high heat generating component 72 attached to one surface of the fixing bracket 70. Coupling groove 51 and a plurality of fastening grooves 53 for coupling after the outer peripheral surface of the heat sink 71 of the late fixing bracket 70 is fixed to the inlet 52 of the coupling groove 51, the coupling The groove 51 is configured to have a connector 54 for connecting the high heat generating component 73 attached to the late fixing bracket 70.

In addition, the fixing bracket 70 attaches a plurality of the high heat generating parts 72 to one surface of the heat dissipation plate 71 of the rectangular plate material having high thermal conductivity, and the coupling groove 51 of the coupling groove 51 on one side of the fixed heat generating parts 72. It is formed to have a socket 75 corresponding to the connector 54 formed on the side, and is formed by continuously attaching a plurality of rectangular thin plate heat radiation fins 73 on the other surface to dissipate heat generated from the high heat generating component (72) In order to attach and detach easily to the coupling groove 51 of the main body 50, the heat dissipation fin 73 is formed to have a handle 74 on the side of the combined surface, the heat sink 71 is the main body portion It is configured to have a fastener (76) corresponding to the fastening groove 53 of the body portion 50 to be fixed and coupled to the engaging groove 51 of the inlet 52 of the 50.

As shown in FIG. 5, the door part 60 may include a surface of the fixing bracket 70 to cover one surface of the main body 50 to which the heat dissipation fin 73 of the fixing bracket 70 protrudes and is coupled. It has an accommodating space for accommodating the heat dissipation fin 73, and is provided with a cooling means for cooling the heat generated in the high heat generating component 72 of the fixing bracket (70).

The cooling means of the door part 60 includes an inlet port 61 for introducing external air into the lower side wall, a cooling fan assembly 62 for forcibly blowing external air introduced from the inlet port 61, and the cooling unit. The air duct 65 for supplying the air forced by the fan combination to the heat radiation fin 73 of the fixed bracket 70 and the air supplied from the air duct 65 to discharge the warmed air after heat exchange It has an air outlet 69 for.

The cooling fan assembly 62 is provided with a cooling fan assembly housing 63 having an inlet port (not shown) inside the inlet port 61 and an outlet port (not shown) at the inlet portion 64 of the air duct. Is mounted.

As shown in FIG. 6, the air duct 65 includes an air distribution plate 66a for adjusting the amount of air discharged from the inlet 64 to the air extraction port 68, and the air distribution plate 66a. ) The rotation support shaft (66b) to support the rotatable, the fixing member (66c) for fixing the rotation support shaft (66b), and the air distribution plate (66a) the amount of the rotation support shaft (66b) An air distributor 66 including a fastener 66d that can be rotated about an end and fixed at a predetermined angle is provided.

Therefore, the amount of air supplied to the fixing bracket 70 is adjusted according to the position of the fixture 66d which fixes the air distribution plate 66a of the air distributor 66 formed at the inlet 64 of the air duct 65. By adjusting it is configured to cool the heat generated in the plurality of fixed brackets 70 in the same way, the air supplied to the outer surface of the heat radiation fin 73 formed in the fixed bracket 70 is forced convection heat exchange, heat Air outlets 69 for discharging the warmed air to the outside are formed on both side surfaces of the door part 60.

Accordingly, the door type outdoor base station of the present invention blows air into which external air flows through the air inlet 61 formed at the lower end of the door part 60 by the cooling fan assembly 62, thereby providing the air duct 65. The air distributor 66 for controlling the amount of cooling air according to the heat generation degree of the high heat generating component 72 to the heat sink 71 and the heat dissipation fins 73 of the plurality of fixing bracket 70 is fixed to the high heat generating component 72 through the Air is distributed through the air outlet port of the fixed bracket 70 through the air extraction port 68 of the air duct 65, and the air is heated by heat exchange. By discharging through the air outlet (69) formed on both sides of the (60), concentrated heating elements to operate in a closed space to concentrate.

As described above, according to the present invention, the cooling efficiency of the high heat generating parts operated in the enclosed space can be directly cooled by inflowing external air to increase the cooling efficiency, and the failure rate can be reduced since the maximum temperature can be lowered when the high heat generating parts are operated. In addition, since the size of the cooling device is reduced due to the increase in the cooling efficiency, the size of the device can be reduced, and the operating temperature of the part can be lowered during the operation of the part. In addition, since the air volume is easily adjusted according to the heat generated by the high heat generating component, the cooling efficiency can be increased, and the high heat generating components can be collected separately to concentrate cooling according to the calorific value, thereby reducing the overall cooling capacity.

Claims (3)

A plurality of high heat generating components, the fixing bracket attached to one surface of the heat sink, and a plurality of rectangular heat sink fins continuously attached to the other surface; A main body portion formed at one outer side of a coupling groove for detachably coupling a plurality of the fixing brackets; And a door part coupled to one side of the main body part so as to be replicably and having a cooling means capable of cooling heat generated from a high heat generating component attached to the fixed bracket. According to claim 1, wherein the cooling means and the inlet for introducing the outside air to the lower end side of the door portion, Cooling fan combination for forcibly blowing the air drawn through the inlet, A cooling fan assembly housing for fixing the cooling fan assembly; An air duct coupled to the cooling fan assembly to supply air; An air distributor for distributing air at the air duct inlet; An air guide plate for guiding the air distributed in the air distributor; An extraction port provided at the front of the air duct for supplying air to heat exchange the air guided along the air guide plate with the high heat generating member of the fixed bracket; Cooling apparatus of the electronic communication equipment, characterized in that the both sides of the door having an air outlet for discharging the air warmed after the heat exchange fin and the heat exchanger of the fixed bracket to the outside. The air distributor of claim 2, wherein the air distributor comprises: an air distribution plate configured to subtract and distribute the air amount according to the heat generation degree of the high heat generating component fixed to the fixed bracket; A rotating support shaft fixed to the air distribution plate to be rotatable, A fixing member for fixing the rotation support shaft; Cooling apparatus of the electronic communication equipment, characterized in that it comprises a plurality of fasteners for fixing the air distribution plate at a predetermined angle to rotate the air distribution plate about the rotation support shaft