CN205088997U - Energy -saving integrated basic station - Google Patents

Abstract

The utility model discloses an energy -saving integrated basic station, construct including the computer lab and through the steel and set up tower body on the computer lab, the tower body inside with the computer lab is inside to be linked together, the top of tower body is equipped with unpowered fan, the air intake has been seted up to the computer lab, the air intake with unpowered fan intercommunication forms the circulation passageway that supplies the air to form the convection current in it. The utility model discloses an energy -saving integrated basic station, the tower body setting reduces the area of basic station on the computer lab, through set up unpowered fan at the tower body top, air intake that the cooperation set up on the computer lab, the circulation passageway that forms of intercommunication supplies the air wherein producing the convection current between the two for air cycle exchange in the computer lab, temperature in the control computer lab, thus reducible or subtract air conditioner setting and the operating duration in the computer lab, realize basic station energy consumption minimizing.

Description

Energy-saving integrated base station

Technical Field

The utility model relates to a communication equipment especially relates to an energy-saving integration basic station.

Background

With the continuous development of the communication industry, base stations are more densely paved, and the required energy consumption is more and more large. At present, the traditional method of the communication base station is to reduce the temperature in a machine room through the continuous operation of an air conditioner, so that a large amount of resources are invested. In order to respond to the national energy-saving requirement, a novel energy-saving integrated base station which can minimize the energy consumption of the base station needs to be designed.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model lies in that, an energy-saving integration basic station that area is little, reduce the energy consumption is provided.

The utility model provides a technical scheme that its technical problem adopted is: the energy-saving integrated base station comprises a machine room and a tower body arranged on the machine room through a steel structure, wherein the interior of the tower body is communicated with the interior of the machine room; the top of the tower body is provided with an unpowered fan, the machine room is provided with an air inlet, and the air inlet is communicated with the unpowered fan to form a circulation channel for air to form convection in the machine room.

Preferably, the bottom of the tower body is sealed by a flange, and a hose is connected between the bottom and the machine room; one end of the hose is arranged on the machine room and communicated with the interior of the machine room, and the other end of the hose is communicated with the interior of the tower body through the flange.

Preferably, heat insulation cotton is further arranged between the bottom of the tower body and the machine room; the heat insulation cotton is attached to the surface of the bottom of the tower body.

Preferably, the steel structure is covered on the periphery of the machine room, and the bottom of the tower body is connected to the steel structure at the top of the machine room.

Preferably, the lower end of the tower body is provided with a drain hole for guiding out the condensed water on the wall surface of the tower body.

Preferably, the outer wall surface of the tower body is provided with a heat absorption coating layer; and/or the presence of a gas in the gas,

the top of tower body still is equipped with decorates the cover, it establishes to decorate the cover the periphery of unpowered fan.

Preferably, the tower body is provided with one or more spaced feeder portions.

Preferably, the feeder line part comprises a feeder line hole penetrating through the interior of the tower body, and an opening of the feeder line hole is inclined downwards towards a relative horizontal line; or,

the feeder line part comprises a single-hole feeder line window penetrating through the interior of the tower body.

Preferably, the tower body is provided with at least one antenna holding pole for mounting an antenna thereon; the antenna holding pole is arranged on the outer wall surface of the tower body and close to the top of the tower body.

Preferably, the air inlet is formed in the lower end of at least one side wall of the machine room;

and a fan is arranged at the air inlet.

Preferably, the air inlet is further provided with one or more of a rain cover, an insect-proof net, a dust-proof net and a shutter.

Preferably, install the intercommunication on the lateral wall of computer lab automatic shutter of computer lab inside and exterior space, installation air conditioner and temperature and humidity sensor in the computer lab, temperature and humidity sensor with air conditioner, automatic shutter intelligence are connected.

The tower body of the energy-saving integrated base station is arranged on the machine room, so that the floor area of the base station is reduced; the unpowered fan is arranged at the top of the tower body and is matched with the air inlet formed in the machine room, the unpowered fan and the air inlet are communicated to form a circulation channel for air to generate convection in the circulation channel, air circulation exchange in the machine room is accelerated, and the temperature in the machine room is controlled, so that the air conditioner setting and the operating time in the machine room can be reduced or subtracted, and the energy consumption of a base station is minimized.

Drawings

The invention will be further explained with reference to the drawings and examples, wherein:

fig. 1 is a schematic structural diagram of an energy-saving integrated base station according to an embodiment of the present invention;

fig. 2 is a schematic diagram of a connection structure between a tower body and a machine room in the energy-saving integrated base station shown in fig. 1;

fig. 3 is a schematic view of air circulation between a tower and a machine room in the energy-saving integrated base station shown in fig. 1;

FIG. 4 is a schematic diagram of an embodiment of a feeder in the energy-saving integrated base station shown in FIG. 1;

FIG. 5 is a schematic diagram of another exemplary feeder in the energy-saving integrated base station shown in FIG. 1;

fig. 6 is a schematic structural diagram of the lower end of the tower body in the energy-saving integrated base station shown in fig. 1.

Detailed Description

In order to clearly understand the technical features, objects, and effects of the present invention, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in fig. 1 and 3, the energy-saving integrated base station according to an embodiment of the present invention includes a machine room 1 and a tower 2 disposed on the machine room 1; the interior of the tower 2 is connected to the interior of the machine room 1 so that air can flow between them. The tower body 2 is arranged on the machine room 1 to form a whole, so that the floor area of the base station is reduced, and the floor area of the base station is mainly determined by the volume of the machine room.

The top of the tower body 2 is provided with an unpowered fan 3, the machine room 1 is provided with an air inlet 10, and the air inlet 10 is communicated with the unpowered fan 3 to form a circulation channel for air to form convection in the air inlet. Air gets into computer lab 1 from air intake 10, inside through circulation passageway circulation to tower body 2, under the cooperation of unpowered fan 3 and air intake 10 for the air is in tower body 2 inside through the chimney effect (the air rises or descends along the space that has the vertical gradient promptly, the phenomenon of the convection current is strengthened to the air that causes), the unpowered fan 3 at 2 height of cooperation tower bodies and top for the air cycle exchange in the computer lab 1, control temperature in the computer lab 1, thereby reduce or subtract the air conditioner setting and the operation in the computer lab 1, realize the minimizing of base station energy consumption.

The unpowered fan 3 is realized by adopting the prior art, and the arc-shaped fan blades are scientifically designed, so that the invasion of rainwater can be strictly avoided under the working state. In addition, the unpowered fan 3 can be seamlessly connected between the top and the tower body 2 through sealant or a sealing ring, and rainwater is further prevented from entering from a gap between the unpowered fan 3 and the tower body 2.

As shown in fig. 1 and 2, the tower body 2 is vertical to the machine room 1 and is arranged above the machine room 1 through a steel structure 21. The steel structure 21 covers the periphery of the machine room 1, and the bottom of the tower body 2 is connected above the steel structure 21 at the top of the machine room 1, so that the tower body 2 is positioned above the machine room 1. The steel structure 21 may be a frame structure made of steel members.

In this embodiment, the bottom of tower body 2 is sealed through flange 22, and is connected with hose 6 between bottom and the computer lab 1, through hose 6 with the inside and the inside intercommunication of tower body 2 of computer lab 1. The hose 6 is one or more. The hose 6 is preferably a rubber bellows hose.

Specifically, the one end setting of hose 6 is on computer lab 1 and with the inside intercommunication of computer lab 1, and the other end of hose 6 passes through flange 22 and the inside intercommunication of tower body 2, and the air circulates between computer lab 1 and tower body 2 through hose 6. One end of the hose 6 is connected with the top plate of the machine room 1 through a hose connector 23, and a gap between the hose connector 23 and the top plate of the machine room 1 is further sealed through glass cement; other positions between the tower body 2 and the top plate of the machine room 1 are sealed, and water inflow of the machine room 1 is avoided.

As shown in fig. 3, heat insulation cotton 7 is further arranged between the bottom of the tower body 2 and the machine room 1, and heat is insulated and conducted between the tower body 2 and the machine room 1 through structural members, so that the service life of each structural member in the machine room 1 is prolonged. Specifically, the heat insulation cotton 7 is attached to the bottom surface of the tower body 2, and does not seal the communication part between the tower body 2 and the machine room 1.

As shown in fig. 1, in order to improve the aesthetic property of the tower body 2, a decorative cover 31 may be further disposed on the top of the tower body 2, and the decorative cover 31 is disposed on the periphery of the unpowered fan 3 to decorate the top of the tower body 2. As shown in fig. 1, in the present embodiment, the decoration cover 31 is a diamond-shaped frame structure; of course, the trim cover 31 may have a frame structure of other shapes such as a sphere and a polygon.

The tower body 2 is provided with one or more spaced feeder sections 4. The plurality of feeder portions 4 may be spaced apart along the height direction of the tower body 2 or may be spaced apart along the circumferential direction of the tower body 2.

As shown in fig. 4, in an embodiment of the feeder part 4, the feeder part 4 includes a feeder hole 41 penetrating through the interior of the tower body 2, and an opening of the feeder hole 41 is inclined downward toward a horizontal line, so that rainwater can be effectively prevented from entering the interior of the tower body 2. The angle of inclination of the feeder hole 41 may preferably be 20 °.

In another embodiment of the feed line section 4, as shown in fig. 5, the feed line section 4 comprises a single aperture feed line window 42 through the interior of the tower body 2. The single-hole feeder window 42 replaces the feeder hole by a through hole with a smaller aperture than the feeder hole, and can also effectively prevent rainwater from entering the tower body 2.

Furthermore, the tower body 2 is provided with at least one antenna holding pole 5 for mounting an antenna thereon. The antenna holding pole 5 is arranged on the outer wall surface of the tower body 2 and close to the top of the tower body 2. As shown in fig. 1, in this embodiment, the antenna holding pole 5 is a frame structure and is fixed to the upper end of the tower body 2 away from the machine room 1.

As shown in fig. 6, a drain hole 24 is formed at the lower end of the tower body 2 to drain the condensed water on the wall surface of the tower body 2. Preferably, the drain holes 24 are arranged at intervals in the circumferential direction of the tower body 2 at the lower end of the tower body 2.

In addition, in order to increase the chimney effect, accelerate the air circulation inside the tower body 2, and reduce the temperature inside the machine room 1 as quickly as possible, the outer wall surface of the tower body 2 may be provided with a heat absorbing paint layer (not shown). The heat-absorbing coating layer can be formed by coating heat-absorbing coating on the outer wall surface and curing, and can also be formed by coating black coating and curing.

The top of the tower body 2 is also provided with a lightning rod 8, as shown in fig. 1. The lightning rod 8 can be fixed on the top middle position of the unpowered fan 3 and also can be fixed on the top of the decorative cover 31.

As also shown in fig. 3, in the present embodiment, the air inlet 10 is opened at the lower end of at least one side wall of the machine room 1.

Furthermore, the air inlet 10 is provided with a fan 11, and the ventilation and the drying in the machine room 1 are ensured through the operation of the fan 11, so that the equipment can operate for a long time. One or more of a rain cover 12, an insect-proof net 13, a dust screen 14 and a shutter 15 can be further arranged at the air inlet 10 to filter air entering the machine room 1, so that the cleanness of the interior of the machine room 1 is guaranteed.

The inside top surface of computer lab 1 is installed the inside automatic shutter 16 of intercommunication computer lab 1 and tower body 2, still installs air conditioner (not shown) and temperature and humidity sensor (not shown) in the computer lab 1, and temperature and humidity sensor and air conditioner, automatic shutter 16 intelligence are connected. The temperature and humidity sensor is also intelligently connected with the fan 11 and the shutter 15. The intelligent connection can realize the corresponding starting or closing of the air conditioner, the automatic shutter 16, the fan 11 and the shutter 15 along with the temperature inside and outside the machine room 1.

When the temperature outside the machine room 1 is high, the ventilation system formed by the unpowered fan 3, the air inlet 10 and the like cannot meet the requirement, when the temperature in the machine room 1 reaches a set value, the automatic shutter 16, the shutter 15 and the fan 11 are automatically closed, the air conditioner is started, the temperature in the machine room 1 is reduced through the air conditioner, and intelligent control is achieved.

In addition, the bottom of the machine room 1 is provided with a counterweight base 9, and the machine room 1 and the tower body 2 are stably positioned on the ground through the counterweight base 9.

The above only is the embodiment of the present invention, not limiting the patent scope of the present invention, all the equivalent structures or equivalent processes that are used in the specification and the attached drawings or directly or indirectly applied to other related technical fields are included in the patent protection scope of the present invention.

Claims (10)

1. An energy-saving integrated base station comprises a machine room (1) and a tower body (2) arranged on the machine room (1) through a steel structure (21), wherein the interior of the tower body (2) is communicated with the interior of the machine room (1); the air conditioner is characterized in that an unpowered fan (3) is arranged at the top of the tower body (2), an air inlet (10) is formed in the machine room (1), and the air inlet (10) is communicated with the unpowered fan (3) to form a circulation channel for air to form convection in the circulation channel.

2. Energy-saving integrated base station according to claim 1, characterized in that the bottom of the tower (2) is closed by a flange (22) and a hose (6) is connected between the bottom and the machine room (1); one end of the hose (6) is arranged on the machine room (1) and is communicated with the interior of the machine room (1), and the other end of the hose (6) is communicated with the interior of the tower body (2) through the flange (22).

3. The energy-saving integrated base station according to claim 2, characterized in that heat insulation cotton (7) is further arranged between the bottom of the tower body (2) and the machine room (1); the heat insulation cotton (7) is attached to the bottom surface of the tower body (2).

4. The energy-saving integrated base station according to claim 1, wherein the steel structure (21) is covered on the periphery of the machine room (1), and the bottom of the tower body (2) is connected to the steel structure (21) at the top of the machine room (1).

5. The energy-saving integrated base station as claimed in claim 1, wherein the lower end of the tower body (2) is provided with a drain hole (24) for guiding out the condensed water on the wall surface of the tower body (2).

6. The energy-saving integrated base station according to claim 1, wherein the outer wall surface of the tower body (2) is provided with a heat-absorbing coating layer; and/or the presence of a gas in the gas,

the top of tower body (2) still is equipped with decorates cover (31), it establishes to decorate cover (31) cover the periphery of unpowered fan (3).

7. The energy efficient all-in-one base station according to claim 1, characterized in that one or more spaced feeder sections (4) are provided on the tower (2);

the feeder part (4) comprises a feeder hole (41) penetrating through the interior of the tower body (2), and the opening of the feeder hole (41) is inclined downwards towards a relative horizontal line; or,

the feeder part (4) comprises a single-hole feeder window (42) penetrating through the interior of the tower body (2).

8. The energy-saving integrated base station according to claim 1, wherein the tower body (2) is provided with at least one antenna holding pole (5) for mounting an antenna thereon; the antenna holding pole (5) is arranged on the outer wall surface of the tower body (2) and is close to the top of the tower body (2).

9. Energy-saving integrated base station according to any one of claims 1 to 8, characterized in that the air inlet (10) is provided in the lower end of at least one side wall of the machine room (1);

a fan (11) is arranged at the air inlet (10);

one or more of a rain cover (12), an insect-proof net (13), a dust-proof net (14) and a shutter (15) are further arranged at the air inlet (10).

10. The energy-saving integrated base station according to any one of claims 1 to 8, wherein an automatic shutter (16) communicating the inside and outside spaces of the machine room (1) is installed on the side wall of the machine room (1), an air conditioner and a temperature and humidity sensor are installed in the machine room (1), and the temperature and humidity sensor is intelligently connected with the air conditioner and the automatic shutter (16).