KR20090014443A - High power repeater for communication and broadcasting with cooling device - Google Patents

Abstract

A high power broadcasting and communicating repeater is provided to improve the lifetime and reliability of equipment due to a cooling structure by forming separate high power electric power amplifying unit containing an independent type heat radiating plate in a box type body. A duct is mounted with a high temperature heat generating unit(140). A protrusion part is formed in one side of a duct and has an air circulating structure. A sub rack(130) is mounted with a low temperature heat generating unit(132). The duct is integrally formed in the box type body (100) and is independently comprised of a detachable sub rack. Also, the duct cools independently the low temperature heat generating unit and the high temperature heat generating unit and blocks the influence on the low temperature heat generating unit caused by the heat generated in the high temperature heat generating unit.

Description

High power repeater for communication and broadcasting with cooling device

The present invention relates to a repeater for broadcasting or communication, and in particular, an essential core part of the repeater, and a high heat generating unit such as a high output amplifier having a large amount of heat generated independently of the low heat generating unit and provides a cooling structure using external air to improve the cooling efficiency The present invention relates to a high power broadcast / communication repeater having a cooling device capable of miniaturization.

In general, a communication or broadcast repeater is a device for relaying transmission and reception between a base station and a terminal, and a combination of various components performs its function. An RF module that processes a high power amplifier, a transmit / receive filter, and an electromagnetic signal And the like.

They consume a lot of power from as few as tens of watts to hundreds of watts depending on transmission loss or power consumption.They generate a lot of heat, and the reliability of the repeater is degraded by the heat generated. Various cooling methods have been proposed to maintain the temperature below a certain level.

As a cooling method of the communication or broadcasting repeater, a cooling method mainly using convection of air is widely used according to the amount of heat generated. Generally, a natural convection method using a heat sink and a forced convection method using a fan and a heat sink are used.

In particular, the cooling method by forced convection greatly affects the performance and the structure of the repeater depending on the cooling structure, so the cooling capacity, size, weight, The installation method is determined.

The cooling method by the forced convection is largely divided into two, the first is a mounting type of the enclosure structure having an external heat sink and a forced cooling fan, which is mainly aluminum on the rear portion of the repeater enclosure 500, as shown in FIG. Air convection by mounting the heat sink 510 in the manner of extrusion, fin bonding, pin press, etc., and installing a fan 520 in the lower part of the enclosure 500 to create forced air flow in the fin direction of the heat sink 510. The fins exposed to the outside are cooled, and thus the heat sink 510 is cooled, so that the high power amplifier 530 attached to the heat sink is cooled, wherein the heat sink 510 and the high power amplifier 530 are cooled. It is a structure to apply or attach TIM (Thermal Interface Material) to reduce thermal contact resistance between floors. Here, one door 540 is provided on the front surface of the enclosure 500, and a heat pipe may be press-fitted to the heat sink 510 to further increase the cooling effect.

Second, a high power amplifier having a heat sink is installed inside the repeater housing to circulate and cool the internal air, and the internal air whose temperature is raised is cooled by a heat exchanger installed inside and outside the enclosure.

However, the first method of attaching the heating element to the heat sink installed on one side of the enclosure has a problem in that the size of the heat sink must be turned on when the heat generator is large, so that the total size of the repeater is increased in weight and size. In addition, since a heat generating element having a high heat generation amount and a heat generating element having a low heat generation amount are attached to one heat sink, heat generated from a high heat generation element is relatively heated because heat generated from the high heat generation element is transferred through the heat sink. Moreover, when attaching the heating element to the heat sink, the TIM should be applied or pasted for the purpose of reducing the contact heat resistance. This process is very demanding, and after a long time, the characteristics of the TIM deteriorate and the reliability is inferior. In addition, there is a method of closely contacting the heating element to the heat sink using a plurality of screws, but this is also a very difficult task. In addition, there is a problem that the temperature rise due to contact thermal resistance is a factor that inhibits cooling.

On the other hand, the second method of cooling the heating element through the air circulation inside and cooling the heated internal air through the heat exchanger has a problem that the heat exchanger itself must be very large, resulting in weight and size and increase in cost. In addition, even if the heat exchange is well done, the internal air temperature is higher than the external air, so the temperature inside the repeater is increased. In addition, since the heat exchanger is mainly installed in the external air and the internal air separately from the centrifugal fan to make the heat exchange with each other, there is a problem that it is difficult to apply to the repeater because of high power consumption and high noise.

The present invention has been proposed to solve the above problems, and has a cooling device that can be configured to provide a cooling structure using an external air and a high heat generating unit such as a high power amplifier independently of the low heat generating unit and to improve the cooling efficiency An object of the present invention is to provide a high power broadcast / communication repeater.

The present invention for achieving the above object is a high heat generating unit heat dissipation unit is formed on one side of the high heat generating portion; And a sub rack on which the high heat generating unit is mounted and a sub rack on which the low heat generating unit is mounted, and an air inlet and an air outlet are formed at one side of the duct.

Preferably, the housing may be installed such that a cooling fan is installed inside the air inlet, and the cooling fan is perpendicular to the heat sink fin of the heat sink.

Preferably, the air outlets are formed at both sides and the rear of one side of the duct, and a protrusion is formed to protrude outward of the enclosure between the air outlets formed at both sides of the duct, and the air inlet is the protrusion. Can be formed on.

Preferably, the high heat generating unit includes a slider formed on the top and bottom surfaces of the high heat generating portion; A front plate formed on the front surface of the high heat generating unit; A guide groove further formed on a rear surface of the front plate, wherein the duct is formed at an upper side and a lower center thereof to correspond to the slider; It may further include an insertion hole into which the connector portion is inserted.

Preferably, the high heat generating unit has a waterproof and EMI gasket is installed on the rear surface of the front plate, a plurality of fastening portions are formed to penetrate the rear surface from the front surface of the front plate, and the duct is mounted on the front surface of the gasket. A support part may be formed, and an insertion groove corresponding to the plurality of fastening parts may be formed.

Preferably, the sub rack is detachable from the enclosure, and an auxiliary cooling fan may be additionally installed.

Preferably, the duct may be formed on both sides of the enclosure.

Preferably, the high heat generating unit includes a high output power amplifier, and the low heat generating unit may be formed of a low heat generating unit including an RF module.

The high output broadcasting / communication repeater having the cooling device according to the present invention has a high output power amplifier unit including a separate heat sink in the structure of the repeater enclosure, thereby effectively cooling and improving the life and reliability of the equipment and reducing the weight and size of the equipment. By achieving this, it is possible to significantly improve the convenience of use and at the same time provide it at low cost.

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

1 is a front view of a high power broadcast / communication repeater having a cooling apparatus according to an embodiment of the present invention, FIG. 2 is a plan view of FIG. 1, and FIG. 3 is a left side view of FIG.

The high power broadcast / communication repeater 10 according to the present invention, as shown in FIG. 1, is formed on one side of the duct 110 and the duct 110 on which the high heat generating unit 140 is mounted to form an air circulation structure. A housing 100 including a protrusion 120 having a protrusion and a sub rack 130 on which the low heat generating unit 132 is mounted; It is composed of a high heat generating unit 140 mounted on the duct 110.

The duct 110 is integrally formed in the enclosure 100 and is configured independently of the detachable sub rack 130, which performs cooling of the low heat generating unit 132 and the high heat generating unit 140 independently. It has a function to block the influence of the low heat generating unit 132 by the heat generated in the high heat generating unit 140.

The duct 110 is formed in the front portion of the high heat generating unit 140 as described later, the waterproof portion and the support portion 112 on which the EMI gasket 149 is seated, and the upper and lower centers of the high heat generating unit 140 are formed. A guide groove 114 corresponding to the slider 148 is formed, and an insertion hole 116 into which the connector portion 145 of the high heat generating unit 140 is inserted is formed at the lower end of the upper slider 148, and the support portion 112 is formed. Insertion grooves 118 corresponding to the plurality of fastening portions 146 of the high heat generating unit 140 are formed at four upper and lower ends.

In addition, the duct 110 is formed on both sides of the housing 100 of the high power broadcast / communication repeater 10, as shown in Figures 1 and 2, on one side and both sides of the high heat generating unit such as a power amplifier Air outlets 124 and 125 for discharging the heated air by contact with the heat sink 143 formed at 142 are formed.

A protrusion 120 is formed between the air outlets 124 formed at both sides of one side of the duct 110 to protrude to the outside of the housing 100 of the high power broadcast / communication repeater 10. An air inlet 122 through which air is introduced is formed.

A cooling fan 126 for introducing air into the protrusion 120 is installed, and the cooling fan 126 is installed at a position corresponding to the air inlet 122, where the cooling fan 126 is an electric power amplifier. In order to provide relatively low temperature outside air to the heat dissipation plate 143 formed on the high heat dissipating part 142 and to increase the effect of convection, it is installed as an impinge type (Impinge Type) so as to be sufficiently connected with the heat dissipation fin of the heat dissipation plate 143. do. That is, the cooling fan 126 is installed to be perpendicular to the heat sink fin of the heat sink 143.

The sub rack 130 is formed in the inner space between the duct 110 on which the high heat generating unit 140 is mounted to form, for example, a low heat generating module having a low heat generation, such as an RF module, in a vertical direction. do.

The sub rack 130 may be detachably configured from the enclosure 100. In this case, a connector (not shown) for connecting a power and a communication cable may be provided on an inner surface of the enclosure 100 in which the sub rack 130 is mounted. Is formed.

In addition, when the heat generating amount of the low heat generating unit 132 is mounted, the sub rack 130 may have an auxiliary cooling fan 134 installed on an upper portion thereof, which circulates internal air to reduce the low heat generating unit 132. Cools the heat generating unit and transfers heat to the enclosure 100 of the high power broadcast / communication repeater 10 to perform natural convection from the enclosure 100 to the atmosphere. Here, when the heat generation amount of the low heat generating unit 132 is large, an additional heat dissipation plate may be installed at the top or the rear of the sub rack 130 so as to exchange heat with external air.

4 is a side view (a), a plan view (b), and a rear view (c) of the high heat generating unit of FIG. 1.

The high heat generating unit 140 includes a high heat generating unit 142 such as a high output power amplifier, a heat sink 143 formed on one side of the high heat generating unit 142, a front plate 144 formed on the front surface of the high heat generating unit 142, and It is composed of a connector portion 145 formed on the back of the front plate (144).

The high heat generating portion 142 is formed of a waterproof structure and a heat sink 143 having a plurality of heat radiation fins on one side thereof is integrally formed. The front panel 144 covers the cable for power supply and communication, and the connector unit 145 has a function of connecting the power and communication cable from the enclosure 100 of the high power broadcast / communication repeater 10, which is a high heat generation unit ( 140 is mounted on the enclosure 100 of the high power broadcast / communication repeater 10 by a plug-in method and a fastening is performed at the same time.

In addition, the high heat generating unit 140 is formed with a plurality of fastening portions 146 to penetrate the rear from the front of the front plate 144 to facilitate mounting on the duct 110, the top and bottom of the high heat generating portion 142 The surface is provided with a slider 148 that fits into the guide groove 114 of the duct 110.

In addition, since the high heat generating unit 140 is configured independently, it is easy to be influenced by the external influence as compared to the one-piece when mounted on the duct 110, so that the internal and external parts are separated when assembling to the enclosure 100 of the high power broadcast / communication repeater 10. The waterproof and EMI gasket 149 is installed at the rear of the front plate 144.

In addition, the high heat generating unit 140 is mounted on the duct 110 that is open to the outside from the inside of the housing 100 of the high power broadcast / communication repeater 10, at this time, the rear of the front plate 144 of the high heat generating unit 140 The waterproof and EMI gasket 149 attached thereto is in close contact with the support 112 of the duct 110 to isolate internal and external air.

The high output broadcasting / communication repeater 10 according to the embodiment of the present invention configured as described above has a high heat generation unit 142 as an independent unit, such as a high frequency power amplifier, which generates relatively high heat and is difficult to cool only by circulation of internal air. Low heat generating unit 132 and provides a separate cooling structure.

That is, the heat sink 143 of the high heat generating portion 142 is exposed to the flow path of the external air through the duct 110 and the outside introduced through the air inlet 122 by the cooling fan 126 installed in the duct 110. By directly contacting the air to the heat sink 143 of the high heat generating portion 142 and discharged to the air outlet 124, it is possible to provide a cooling structure dedicated to the high heat generating portion 142 to improve the cooling efficiency.

At this time, the duct 110 and the sub rack 130 is formed independently, as shown in Figure 2, a constant distance between the high heat generating unit 140 and the sub rack 130 mounted on the duct 110, Since it is formed, the low heat generating unit 132 mounted in the sub rack 130 is not affected by the heat generated in the high heat generating unit 140.

Meanwhile, when the high heat generating unit 140 is assembled to the housing 100 of the high output broadcasting / communication repeater 10, that is, when the high heat generating unit 140 is mounted on the duct 110, the waterproof unit 140 is installed on the rear surface of the front plate 144 of the high heat generating unit 140. EMI gasket 149 is in close contact with the support portion 112 formed in the front portion of the duct 110 and fixed by the fastening portion 146, the outside air and the internal air based on the front plate 144 completely blocked and cooled Efficiency and reliability of operation can be guaranteed.

In addition, when the high heat generating unit 140 is mounted on the duct 110, the slider 148 of the high heat generating unit 140 is guided along the guide groove 114 of the duct 110, and at the same time, the plug unit 145 is connected. Can be easily mounted by the configuration.

As described above, the high power broadcast / communication repeater 10 according to the present invention independently configures the duct 110 and the low heat generating unit 132 on which the high heat generating unit 140 including the high heat generating unit 142 is mounted. By improving the problem of the mounting efficiency by the high heat generating unit 142 can be achieved at a small size and light weight can be provided at a low cost.

1 is a front view of a high power broadcast / communication repeater having a cooling device according to an embodiment of the present invention.

2 is a plan view of FIG.

3 is a left side view of FIG. 1;

4 is a side view (a), a plan view (b) and a rear view (c) of the high heat generating unit of FIG.

5 is a plan view (a), a partially cut back view (b), and a partial side cross-sectional view (c) of a conventional repeater enclosure.

Explanation of symbols on the main parts of the drawings

10: high power broadcast / communication repeater 100: enclosure

110: duct 112: support

114: guide groove 116: insertion hole

118: insertion groove 120: protrusion

122, 125: air inlet 124: air outlet

126: cooling fan 130: sub rack

132: low heat generation unit 134: auxiliary cooling fan

140: high heat generating unit 142: high heat generating unit

143: heat sink 144: front panel

145: connector portion 146: fastening portion

148: Slider 149: Waterproof and EMI Gasket

Claims (8)

A high heat generating unit having a heat sink formed on one side of the high heat generating unit; It has a duct on which the high heat generating unit is mounted and a sub rack on which the low heat generating unit is mounted, an enclosure having an air inlet and an air outlet formed on one side of the duct; Repeater. The method of claim 1, The housing is a high power broadcast / communication repeater having a cooling device, characterized in that the cooling fan is installed inside the air inlet is installed so that the cooling fan is perpendicular to the heat sink fin of the heat sink. The method of claim 2, The air outlets are formed at both sides and the rear side of one side of the duct, and protrusions are formed to protrude outward of the enclosure between the air outlets formed at both sides of one side of the duct, and the air inlet is formed at the protrusion. High power broadcast / communication repeater having a cooling device, characterized in that. The method of claim 2, The high heat generating unit includes a slider formed on the top and bottom surfaces of the high heat generating portion; A front plate formed on the front surface of the high heat generating unit; Further comprising a connector portion formed on the rear of the front plate, The duct is formed in the upper and lower center of the guide groove corresponding to the slider; High-power broadcast / communication repeater having a cooling device, characterized in that it further comprises an insertion hole into which the connector is inserted. The method of claim 4, wherein The high heat generating unit is a waterproof and EMI gasket is installed on the rear of the front plate, a plurality of fastening portions are formed to penetrate the rear from the front of the front plate, The duct is a high-power broadcast / communication repeater having a cooling device, characterized in that the front portion is formed with a support portion for seating the gasket, the insertion groove corresponding to the plurality of fastening portion is formed. The method of claim 2, The sub rack is detachable from the housing, and a high power broadcast / communication repeater having a cooling device, characterized in that the additional cooling fan is installed. The method of claim 2, The duct is a high power broadcast / communication repeater having a cooling device, characterized in that formed on both sides of the enclosure. The method of claim 2, And the high heat generating unit comprises a high output power amplifier, and the low heat generating unit comprises a low heat generating unit including an RF module.

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