TWI611149B - Air conditioning substation energy-saving heat dissipation structure - Google Patents

Description

Air conditioning substation energy-saving heat dissipation structure

The invention relates to an energy-saving heat-dissipating structure, and more particularly to an energy-saving heat-dissipating structure of an air-conditioning substation, which can directly derive the heat of the internal heating part of the transformer box, so that the heat is insulated from the substation air-conditioning space, improve the heat dissipation effect of the air-conditioning substation, and reduce The setting or operation of air conditioning cooling equipment reduces electricity bills.

The current air conditioning substation is shown in Figure 1. A plurality of transformer boxes 1 and a plurality of air conditioner cooling devices 2 are provided in a machine room H. The transformer boxes 1 include power equipment and transformers, and are used in a disk surface or a disk top. The fan exhausts the heat in the transformer box 1 in a heat convection manner, and the number of the air conditioner cooling devices 2 increases according to the number of the transformer boxes 1, thereby reducing the temperature of the equipment room H, thereby indirectly The internal temperature of the transformer box 1 is lowered.

However, in the current air conditioning substation, the number of such air conditioning cooling devices 2 increases with the number of such substation boxes 1, resulting in a larger air conditioning substation requiring a larger number of air conditioning cooling devices 2, in other words, for cooling. The electricity bill is very amazing.

Therefore, how to invent an energy-saving heat-dissipating structure, installed in an air-conditioning substation, to improve the heat-dissipating effect of the air-conditioning substation, and to reduce the setting of the air-conditioning cooling device, thereby reducing the setting or operation of the electricity fee, the air-conditioning cooling device, and the like Actively expose the place.

The object of the present invention is to provide an energy-saving and heat-dissipating structure for an air-conditioning substation, which is used for improving the heat dissipation effect of the air-conditioning substation and reducing the electricity cost.

To achieve the above and other objects, the present invention provides an energy-saving heat dissipation structure for an air-conditioning substation, which is disposed in an air-conditioning substation having a plurality of transformer boxes and at least one air-conditioning cooling device, the transformer boxes and the air-conditioning cooling device setting In a machine room, the energy-saving heat dissipation structure of the air-conditioning substation comprises: an air inlet, which is disposed on a wall surface of the machine room; an exhaust port, which is disposed on another wall surface of the machine room; and a heat exchange ventilation pipe body Provided in the machine room, the two ends of the heat exchange ventilation pipe body respectively communicate with the air inlet and the air outlet; at least one air guiding fan is installed in the heat exchange ventilation pipe body to guide the gas from the The air inlet flows to the air outlet; a plurality of heat dissipation fins are disposed on the heat exchange ventilation tube body; and a plurality of heat conduction devices, wherein each of the two ends of the heat conduction device is respectively connected with a heat dissipation fin and an internal heat of the transformer box unit.

In the energy-saving and heat-dissipating structure of the air-conditioning substation of the present invention, the air-conducting fan is two, respectively adjacent to the air inlet and the air outlet.

In the energy-saving and heat-dissipating structure of the air-conditioning substation of the present invention, the air-conducting fan close to the air inlet is an air suction fan, and the air-conducting fan close to the air outlet is an exhaust fan.

In the energy-saving and heat-dissipating structure of the air-conditioning substation of the present invention, the number of the heat-dissipating fins and the heat-conducting devices respectively correspond to the number of power-changing boxes.

In summary, the energy-saving and heat-dissipating structure of the air-conditioning substation of the present invention can improve the heat-dissipating effect of the air-conditioning substation and reduce the setting or operation of the electric power meter and the air-conditioning cooling device by setting a small number of air-conditioning cooling devices.

10‧‧‧air inlet

20‧‧‧Exhaust port

30‧‧‧Heat exchange ventilation pipe body

31‧‧‧ first end

32‧‧‧second end

40‧‧‧Air guide fan

40a‧‧‧Inhalation fan

40b‧‧‧Exhaust fan

50‧‧‧ Heat sink fins

60‧‧‧heat conduction device

61‧‧‧ first end

62‧‧‧ second end

100‧‧‧Air-conditioning substation energy-saving heat dissipation structure

200‧‧‧Air-conditioning substation energy-saving heat dissipation structure

1000‧‧‧Air conditioning substation

1100‧‧‧Transformation box

1110‧‧‧Internal heating department

1200‧‧‧Air conditioning and cooling equipment

H‧‧‧ machine room

W1‧‧‧ wall

W2‧‧‧ another wall

[Fig. 1] is a schematic view of a conventional air conditioning substation.

FIG. 2 is a schematic view showing a first embodiment of an energy-saving and heat-dissipating structure of an air-conditioning substation according to the present invention.

FIG. 3 is a schematic view showing a second embodiment of the energy-saving and heat-dissipating structure of the air-conditioning substation of the present invention.

In order to fully understand the object, features and advantages of the present invention, the present invention will be described in detail by the following specific embodiments and the accompanying drawings, which are illustrated as follows: A schematic diagram of a first embodiment of an air-conditioning substation energy-saving heat dissipation structure 100 is provided. The air-conditioning substation energy-saving heat dissipation structure 100 is disposed in an air-conditioning substation 1000. The air-conditioning substation 1000 has a plurality of power-changing boxes 1100 and at least one air-conditioning cooling device 1200. The electric box 1100 and the air conditioning cooling device 1200 are disposed in a machine room H. The air conditioning substation energy-saving heat dissipation structure 100 comprises: an air inlet 10, an air outlet 20, a heat exchange ventilation tube body 30, and at least one air guiding fan. 40. A plurality of heat sink fins 50 and a plurality of heat conducting devices 60.

In the first embodiment, the air inlet 10 is disposed through a wall W1 of the machine room H; the air outlet 20 is disposed through another wall W2 of the machine room H, the wall W1 and the other wall The wall surface W2 may be located at both ends of the machine room H, but is not limited thereto. In addition, the air inlet 10 preferably includes a filter mesh, and the exhaust port 20 preferably includes an insect net.

The heat exchange ventilation pipe body 30 is disposed in the machine room H, and the two ends of the heat exchange ventilation pipe body 30 respectively communicate with the air inlet port 10 and the air outlet port 20; more specifically, as shown in FIG. The first end 31 of the heat exchange vent tube body 30 is in communication with the air inlet 10, and the second end 32 of the heat exchange vent tube body 30 is in communication with the exhaust port 20. In the first embodiment, since the wall surface W1 and the other wall surface W2 are respectively located at two ends of the machine room H, the air inlet 10 and the air outlet 20 are respectively located at two ends of the machine room H. (ie, the left side and the right side of FIG. 2), the heat exchange ventilation pipe body 30 is disposed from the left side to the right side in FIG. 2; accordingly, the heat exchange ventilation pipe body 30 according to the air inlet port 10 and the exhaust port 20 The position changes and does not necessarily go straight.

The air guiding fan 40 is installed in the heat exchange ventilation pipe body 30 to guide the flow of gas from the air inlet 10 to the exhaust port 20; more specifically, the air outside the machine room H is from the air inlet 10 It is guided into the heat exchange vent pipe body 30 and is again discharged from the exhaust port 20 to the outside of the machine room H.

The heat dissipation fins 50 are disposed in the heat exchange ventilation tube body 30. As shown in FIG. 2, the heat dissipation fins 50 are disposed in the tube of the heat exchange ventilation tube body 30, but are not limited thereto, and may be disposed. On the outer tube wall of the heat exchange vent tube body 30.

Each of the two ends of the heat conducting device 60 is connected to a heat dissipating fin 50 and an internal heat generating portion 1110 of the transformer box 1100; more specifically, the first end 61 of each heat conducting device 60 is connected to a heat sink fin 50. The second end 62 of each of the heat conducting devices 60 is connected to the internal heat generating portion 1110 of the transformer box 1100; thereby, each of the heat conducting devices 60 conducts heat generated by the internal heat generating portion 1110 to each of the heat radiating fins 50.

As described above, when the air inlet 10 guides cold air from the outside of the machine room H into the heat exchange ventilation pipe body 30 (as indicated by the solid arrow on the left side in FIG. 2), each of the heat conducting devices 60 will After the heat generated by the internal heat generating portion 1110 is transmitted to each of the heat radiating fins 50 (shown by wavy arrows in FIG. 2), the heat transmitted to each of the heat radiating fins 50 is again in the tube of the heat exchange vent tube body 30. The air is heat exchanged and discharged from the exhaust port 20 to the outside of the machine room H (as indicated by the dotted arrow in Fig. 2). Thereby, the transformer box 1100 of the air conditioner substation 1000 is caused to dissipate heat.

In addition, as shown in FIG. 2, the number of the heat dissipation fins 50 and the heat transfer devices 60 need not be the same as the number of the heat transfer boxes 1100, but the heat dissipation fins 50 and the heat transfer devices 60 When the number is equal to 1100 of the number of transformer boxes, the heat dissipation effect is even more.

The air-conditioning substation energy-saving heat dissipation structure 100 of the present invention directly exchanges heat with the heat generated by the internal heat-generating portion 1110 by the cold air outside the equipment room H, so that the heat is isolated from the substation air-conditioning space, thereby reducing the air-conditioning cooling device 1200 to cool down. According to this, in the case where a small number of air conditioning cooling devices 1200 are provided, the heat dissipation effect is still high, so that the electricity cost can be effectively reduced.

Next, please refer to FIG. 3 , which is a schematic diagram of a second embodiment of the energy-saving heat dissipation structure 200 of the air conditioning substation of the present invention. The components of the air-conditioning substation energy-saving heat dissipation structure 200 are substantially the same as the components of the air-conditioning substation energy-saving heat dissipation structure 100, wherein the air-conducting fans are two, respectively adjacent to the air inlet 10 and the air outlet 20; more specifically The air guiding fan close to the air inlet 10 is the air suction fan 40a, and the air guiding fan close to the air outlet port 20 is the exhaust fan 40b, thereby increasing the speed of gas flow and further making heat exchange faster.

In summary, the energy-saving and heat-dissipating structure of the air-conditioning substation of the present invention can improve the heat-dissipating effect of the air-conditioning substation and reduce the setting or operation of the electric power meter and the air-conditioning cooling device by setting a small number of air-conditioning cooling devices.

The invention has been described above in terms of the preferred embodiments, and it should be understood by those skilled in the art that the present invention is not intended to limit the scope of the invention. It should be noted that variations and permutations equivalent to those of the embodiments are intended to be included within the scope of the present invention. Therefore, the scope of protection of the present invention is defined by the scope of the patent application.

10‧‧‧air inlet

20‧‧‧Exhaust port

30‧‧‧Heat exchange ventilation pipe body

31‧‧‧ first end

32‧‧‧second end

40‧‧‧Air guide fan

50‧‧‧ Heat sink fins

60‧‧‧heat conduction device

61‧‧‧ first end

62‧‧‧ second end

100‧‧‧Air-conditioning substation energy-saving heat dissipation structure

1000‧‧‧Air conditioning substation

1100‧‧‧Transformation box

1110‧‧‧Internal heating department

1200‧‧‧Air conditioning and cooling equipment

H‧‧‧ machine room

W1‧‧‧ wall

W2‧‧‧ another wall

Claims (4)

An air-conditioning substation energy-saving heat dissipation structure is disposed in an air-conditioning substation, the air-conditioning substation has a plurality of transformer boxes and at least one air-conditioning cooling device, wherein the transformer boxes and the air-conditioning cooling device are disposed in a machine room, and the air-conditioning substation energy-saving heat dissipation structure The utility model comprises: an air inlet, which is disposed on a wall surface of the machine room; an exhaust port, which is disposed on another wall surface of the machine room; a heat exchange ventilation pipe body disposed in the machine room, and the heat exchange The two ends of the ventilation pipe body respectively communicate with the air inlet and the air outlet; at least one air guiding fan is installed in the heat exchange ventilation pipe body to guide the flow of gas from the air inlet to the air outlet; The fins are disposed on the heat exchange ventilation tube body; and a plurality of heat conduction devices, wherein each of the two ends of the heat conduction device is respectively connected with a heat dissipation fin and an internal heat generating portion of the transformer box. The air-conditioning substation energy-saving heat dissipation structure according to claim 1, wherein the air-conducting fan is two, respectively adjacent to the air inlet and the air outlet. The air conditioning substation energy-saving heat dissipation structure according to claim 2, wherein the air guiding fan close to the air inlet is an air suction fan, and the air guiding fan close to the air outlet is an exhaust fan. The energy-saving heat-dissipating structure of the air-conditioning substation according to any one of claims 1 to 3, wherein the number of the heat-dissipating fins and the heat-conducting devices respectively correspond to the number of power-changing boxes.