CN210351955U - Energy-saving system for constant temperature adjustment of communication base station - Google Patents

Abstract

The utility model discloses an energy-saving system for constant temperature adjustment of a communication base station, which comprises a base station main body and a base station base, wherein a photovoltaic power generation board is arranged on the top of the base station main body, a constant temperature controller, a refrigerator and a photovoltaic control box are arranged on a partition board of the base station main body, and an equipment box body is arranged in the base station main body; the bottom of the equipment box body is provided with a water storage tank, a floating plate of the water storage tank is connected with a capillary tube bundle in a penetrating manner, and the water storage tank is connected with an internal circulating water pipe through a first water pump; the inner wall of the equipment box body and the double-layer metal grids are provided with serpentine heat exchange tubes; a metal heat exchange tube is arranged in a heat exchange water tank on the top of the equipment box body and is connected with a refrigerator; the base station main body is externally provided with a heat dissipation box and a filtering water tower, and the heat dissipation box is provided with an annular coil pipe and an atomizing spray head. The utility model discloses a multiple rivers cooling mode, the nothing needs powerful air conditioner, compressor and fan, thereby can effectively guarantee the constant temperature state in the equipment box and improve the operating stability of basic station part by a wide margin to operating power reduces by a wide margin, has the energy-conserving effect of preferred.

Description

Energy-saving system for constant temperature adjustment of communication base station

Technical Field

The utility model relates to a communication base station heat dissipation technical field especially relates to an economizer system for communication base station constant temperature adjusts.

Background

According to statistics of relevant data, the annual power consumption total amount of the air conditioner of the communication base station accounts for 46% of the annual power consumption total amount of the whole equipment room. Therefore, on the premise of ensuring that the temperature, the humidity, the cleanliness and the like of the base station meet the requirements, how to effectively reduce the service time of the air conditioner of the base station and reduce the power consumption becomes an important work for saving energy of the communication base station.

The existing energy-saving products of the communication base station mainly comprise a temperature compensation control air conditioner electricity saver, an intelligent fresh air system, an intelligent heat exchange system, an air conditioner additive, an air conditioner heat exchanger, a nano coating technology and a heat insulation coating technology. The energy-saving effect of the novel product cannot fundamentally solve the strong dependence on the air conditioner, once power failure or circuit failure occurs, the temperature in the communication base station is rapidly increased, and irreversible damage is caused to communication parts.

Therefore, if a heat dissipation system independent of an air conditioner can be developed, a great innovation will be brought to the heat dissipation technology of the communication base station.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the shortcoming that exists among the prior art, and the economizer system who is used for communication base station thermostatic control who proposes.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

an energy-saving system for constant temperature regulation of a communication base station comprises a base station main body and a base station base, wherein a photovoltaic power generation board is installed at the top of the base station main body, a partition board is erected on the inner side of the base station main body, a constant temperature controller, a refrigerator and a photovoltaic control box are arranged on the partition board, a photovoltaic inverter, a voltage stabilizer and a storage battery are arranged in the photovoltaic control box, an equipment box body is arranged in the base station main body, the equipment box body is installed on the upper surface of the base station base, and the equipment box body is located below;

the bottom of the equipment box body is provided with a water storage tank, a floating plate is arranged in the water storage tank, capillary tube bundles are connected to the floating plate in a penetrating manner, one end, far away from the floating plate, of each capillary tube bundle penetrates out of the water storage tank and extends into the equipment box body, the water storage tank is communicated with a first water pump through a pipeline, and the first water pump is connected with an internal circulating water pipe;

a double-layer metal grid is erected in the middle of the equipment box body, a snake-shaped heat exchange tube is clamped in the double-layer metal grid, the snake-shaped heat exchange tube is also paved on the inner wall of the equipment box body, and the snake-shaped heat exchange tube is communicated with the internal circulating water tube;

the top of the equipment box body is provided with a heat exchange water tank, the heat exchange water tank is communicated with the internal circulating water pipe, a metal heat exchange pipe is arranged in the heat exchange water tank and is connected with the refrigerator, the refrigerator is preferably a semiconductor refrigerator and is divided into a cold end and a hot end, and the cold end is in contact connection with the metal heat exchange pipe;

the outer wall of the base station main body is provided with a heat dissipation box and a filtering water tower, an annular coil pipe is erected in the heat dissipation box, one end of the annular coil pipe is communicated with an internal circulating water pipe, the other end of the annular coil pipe is communicated with the filtering water tower through a pipeline, the filtering water tower is also connected with a second water suction pump, the second water suction pump is connected with a spray pipe, one end, away from the second water suction pump, of the spray pipe extends to the upper portion of the heat dissipation box, and one end, away from the second water suction pump, of the spray;

and temperature sensors are arranged in the equipment box body and the heat dissipation box.

Preferably, two opposite side walls of the heat dissipation box are provided with fan openings, and the top of the heat dissipation box is provided with a sun screen.

Preferably, the top of the filtering water tower is an opening, and a filter element is arranged at the opening of the filtering water tower.

Preferably, the upper part of the filtering water tower is provided with an overflow pipe which is communicated with the water storage tank.

Preferably, the size of the seam between the water storage tank and the capillary tube bundle is 1-2 mm.

Preferably, exhaust fans are provided at both upper and lower positions of the base station main body.

Compared with the prior art, the beneficial effects of the utility model are that:

the utility model discloses a multiple cooling mode, first heavy cooling: the exhaust fan and the capillary tube bundle are used for ventilating and cooling; and (4) second cooling: the snakelike heat exchange tube and the internal circulating water tube are cooled by water; and (3) cooling again: the heat exchange water tank, the metal heat exchange pipe and the refrigerator refrigerate and cool the internal circulating water pipe; fourthly, cooling: the heat dissipation box, the spray head, the fan opening and the annular coil pipe are used for spraying and cooling the internal circulating water pipe. Under the supporting action of solar energy, the utility model discloses can set up the remote area of keeping away from the electric wire netting, and the utility model discloses a multiple cooling mode, nothing needs powerful air conditioner, compressor and fan, under thermostatic control ware and temperature sensor's cooperation, can effectively guarantee the constant temperature state (0-10 ℃) in the equipment box body to improve the operating stability of basic station part by a wide margin, and operating power reduces by a wide margin, has the energy-conserving effect of preferred.

Drawings

Fig. 1 is an internal structure diagram of an energy saving system for thermostatic regulation of a communication base station according to the present invention;

fig. 2 is a back view of an energy saving system for thermostatic regulation of a communication base station according to the present invention;

fig. 3 is a perspective view of a heat dissipation box of an energy saving system for thermostatic regulation of a communication base station according to the present invention;

fig. 4 is a schematic structural diagram of the annular coil pipe of the energy saving system for thermostatic regulation of the communication base station according to the present invention.

In the figure: the base station comprises a base station main body 1, a base station 2, a photovoltaic power generation board 3, a partition board 4, a thermostatic controller 5, a refrigerator 6, a photovoltaic control box 7, an equipment box body 8, a water storage tank 9, a floating board 10, a capillary tube bundle 11, a first water pump 12, an internal circulating water pipe 13, a double-layer metal grid 14, a serpentine heat exchange pipe 15, a heat exchange water tank 16, a metal heat exchange pipe 17, a heat dissipation tank 18, a filtering water tower 19, a ring-shaped coil pipe 20, a second water pump 21, a spray pipe 22, a spray head 23, a temperature sensor 24, a fan opening 25, a sun screen 26, a filter core 27, an overflow pipe 28 and an exhaust fan 29.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

Referring to fig. 1-4, an energy-saving system for thermostatic regulation of a communication base station comprises a base station main body 1 and a base station base 2, wherein a photovoltaic power generation panel 3 is installed at the top of the base station main body 1, a partition plate 4 is erected on the inner side of the base station main body 1, a thermostatic controller 5, a refrigerator 6 and a photovoltaic control box 7 are arranged on the partition plate 4, an equipment box body 8 is arranged inside the base station main body 1, the equipment box body 8 is installed on the upper surface of the base station base 2, and the equipment box body 8 is located below the partition plate 4; a water storage tank 9 is arranged at the bottom of the equipment box body 8, a floating plate 10 is arranged in the water storage tank 9, a capillary tube bundle 11 is connected to the floating plate 10 in a penetrating manner, one end, far away from the floating plate 10, of the capillary tube bundle 11 penetrates out of the water storage tank 9 and extends into the equipment box body 8, the water storage tank 9 is communicated with a first water pump 12 through a pipeline, and the first water pump 12 is connected with an internal circulating water pipe 13; a double-layer metal grid 14 is erected in the middle of the equipment box body 8, a snake-shaped heat exchange tube 15 is clamped in the double-layer metal grid 14, the snake-shaped heat exchange tube 15 is also paved on the inner wall of the equipment box body 8, and the snake-shaped heat exchange tube 15 is communicated with the internal circulating water tube 13; a heat exchange water tank 16 is arranged at the top of the equipment box body 8, the heat exchange water tank 16 is communicated with the internal circulating water pipe 13, a metal heat exchange pipe 17 is arranged in the heat exchange water tank 16, and the metal heat exchange pipe 17 is connected with the refrigerator 6; the outer wall of the base station main body 1 is provided with a heat dissipation box 18 and a filtering water tower 19, an annular coil pipe 20 is erected on the inner wall of the heat dissipation box 18, one end of the annular coil pipe 20 is communicated with the internal circulation water pipe 13, the other end of the annular coil pipe 20 is communicated with the filtering water tower 19 through a pipeline, the filtering water tower 19 is also connected with a second water suction pump 21, the second water suction pump 21 is connected with a spray pipe 22, one end, far away from the second water suction pump 21, of the spray pipe 22 extends to the upper portion of the heat dissipation box 18, and one end, far away from the second water suction pump 21; temperature sensors 24 are arranged in the equipment box body 8 and the heat dissipation box 18.

Referring to fig. 3, two opposite side walls of the heat dissipation box 18 are provided with fan openings 25, the top of the heat dissipation box 18 is provided with a sun screen 26, the fan openings 25 blow, and the temperature of the pipe wall of the annular coil 20 is far lower than the room temperature under the spraying action of the spraying heads 23.

Referring to fig. 1-4, the top of the filtering water tower 19 is an opening, and a filter element 27 is disposed at the opening of the filtering water tower 19, so that the filtering water tower 19 can store natural rainwater, thereby reducing the municipal water supply amount.

Referring to fig. 3, the upper portion of the filtering water tower 19 is provided with an overflow pipe 28, the overflow pipe 28 is communicated with the water storage tank 9, the size of the joint between the water storage tank 9 and the capillary tube bundle 11 is 1-2mm, and the overflow pipe 28 is used for providing a certain water pressure to the water storage tank 9, so that the water is continuously seeped from the top of the capillary tube bundle 11 and falls back into the water storage tank 9, a certain humidity in the equipment box 8 is ensured, the cooling effect can be improved, and meanwhile, the electrostatic phenomenon can be avoided.

Referring to fig. 2, exhaust fans 29 are provided at upper and lower portions of the base station body 1 to ventilate the base station body 1 and take away excess moisture in the equipment cabinet 8, thereby ensuring dryness and coolness in the equipment cabinet 8.

The utility model discloses a working process: the utility model discloses a multiple cooling mode, first heavy cooling: an exhaust fan 29 and a capillary bundle 11 for cooling; and (4) second cooling: the snakelike heat exchange tube 15 and the internal circulating water tube 13 are cooled by water; and (3) cooling again: the heat exchange water tank 16, the metal heat exchange tube 17 and the refrigerator 6 refrigerate and cool the internal circulating water tube 13; fourthly, cooling: the heat dissipation box 18, the spray head 23, the fan port 25 and the annular coil pipe 20 are used for spraying and cooling the internal circulating water pipe 13. Under the supporting action of solar energy, the utility model discloses can set up the remote area who keeps away from the electric wire netting, and the utility model discloses a multiple cooling mode, nothing needs powerful air conditioner, compressor and fan, under thermostatic control 5 and temperature sensor 24's cooperation, can effectively guarantee constant temperature state (0-10 ℃) in the equipment box 8 to improve the operating stability of basic station part by a wide margin, and operating power reduces by a wide margin, has the energy-conserving effect of preferred.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (6)

1. An energy-saving system for constant temperature adjustment of a communication base station comprises a base station main body (1) and a base station base (2), and is characterized in that a photovoltaic power generation board (3) is installed at the top of the base station main body (1), a partition board (4) is erected on the inner side of the base station main body (1), a constant temperature controller (5), a refrigerator (6) and a photovoltaic control box (7) are arranged on the partition board (4), an equipment box body (8) is arranged inside the base station main body (1), the equipment box body (8) is installed on the upper surface of the base station base (2), and the equipment box body (8) is located below the partition board (4);

the water storage tank is characterized in that a water storage tank (9) is arranged at the bottom of the equipment box body (8), a floating plate (10) is arranged in the water storage tank (9), a capillary tube bundle (11) is connected to the floating plate (10) in a penetrating manner, one end, far away from the floating plate (10), of the capillary tube bundle (11) penetrates out of the water storage tank (9) and extends into the equipment box body (8), the water storage tank (9) is communicated with a first water suction pump (12) through a pipeline, and the first water suction pump (12) is connected with an internal circulation water pipe (13);

a double-layer metal grid (14) is erected in the middle of the equipment box body (8), a snake-shaped heat exchange tube (15) is clamped in the double-layer metal grid (14), the inner wall of the equipment box body (8) is also paved with the snake-shaped heat exchange tube (15), and the snake-shaped heat exchange tube (15) is communicated with the internal circulating water pipe (13);

a heat exchange water tank (16) is arranged at the top of the equipment box body (8), the heat exchange water tank (16) is communicated with the internal circulating water pipe (13), a metal heat exchange pipe (17) is arranged in the heat exchange water tank (16), and the metal heat exchange pipe (17) is connected with the refrigerator (6);

the base station comprises a base station main body (1) and is characterized in that a heat dissipation box (18) and a filtering water tower (19) are arranged on the outer wall of the base station main body (1), an annular coil pipe (20) is erected in the heat dissipation box (18), one end of the annular coil pipe (20) is communicated with an internal circulation water pipe (13), the other end of the annular coil pipe (20) is communicated with the filtering water tower (19) through a pipeline, the filtering water tower (19) is further connected with a second water suction pump (21), the second water suction pump (21) is connected with a spray pipe (22), one end, far away from the second water suction pump (21), of the spray pipe (22) extends to the upper portion of the heat dissipation box (18), and one end, far away from the second water suction pump (21), of;

and temperature sensors (24) are arranged in the equipment box body (8) and the heat dissipation box (18).

2. An energy saving system for communication base station thermostat regulation according to claim 1 characterized in that two opposite side walls of the heat dissipation box (18) are provided with fan openings (25), and the top of the heat dissipation box (18) is provided with a sun screen (26).

3. The energy-saving system for thermostatic regulation of communication base station as claimed in claim 1, characterized in that the top of the filtering water tower (19) is open, and the filtering core (27) is arranged at the opening of the filtering water tower (19).

4. An energy saving system for the thermostatic regulation of communication base stations according to claim 3 characterized in that the upper part of the filtering water tower (19) is provided with an overflow pipe (28), the overflow pipe (28) being in communication with the storage tank (9).

5. An energy saving system for thermostatic regulation of communication base stations according to claim 1 characterized by that the size of the joint of the water storage tank (9) and the capillary tube bundle (11) is 1-2 mm.

6. An energy saving system for thermostat regulation of communication base stations according to claim 1, characterized in that exhaust fans (29) are provided at both upper and lower positions of the base station body (1).

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