CN216820008U - Energy-saving communication switching equipment - Google Patents

Abstract

The utility model belongs to the technical field of communication exchange equipment, in particular to energy-saving communication exchange equipment, which comprises a base and an engine body arranged above the base, wherein a mounting plate is arranged above the base, supporting columns are connected between four corners below the mounting plate and the upper surface of the base, the engine body is arranged above the mounting plate, a through hole penetrating to the upper surface of the mounting plate is formed in the mounting plate, a plurality of radiating pipes which are distributed at equal intervals are fixed in the through hole, the upper surfaces of the radiating pipes are attached to the lower surface of the engine body, the radiating pipes are used for radiating the bottom surface of the engine body, a circulating assembly is arranged above the engine body and used for cooling liquid in the radiating pipes; according to the utility model, the heat is continuously radiated from the lower part of the machine body through the radiating pipe, the phenomenon that the energy consumption is increased due to overhigh temperature of the exchange equipment during working caused by overheating of parts in the machine body is avoided to a certain extent, the power of the fan is adjusted according to the actual temperature, the waste of energy is effectively avoided, and the energy is saved.

Description

Energy-saving communication switching equipment

Technical Field

The utility model relates to the technical field of communication switching equipment, in particular to energy-saving communication switching equipment.

Background

Communication exchange equipment is a common equipment that is used for the exchange of signals, install a plurality of sockets on the exchange of signals in order to supply different electronic equipment to use, current exchange of signals equipment can be equipped with radiator fan usually and dispel the heat in order to guarantee the normal work of organism to the organism, and the equipment organism is placed on the plane usually, and the organism bottom is also more because the heat that the part of installation distributes more, the difficult better heat dissipation of equipment bottom placed on the plane, lead to equipment too high and cause the condition that the power consumption increases at the during operation temperature easily, current exchange of equipment fan for the heat dissipation carries out the work that lasts with certain power usually, cause the waste of more energy easily.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the problems and the defects, and provides the energy-saving communication exchange equipment, which continuously dissipates heat below the machine body through a heat dissipation pipe, avoids energy consumption increase caused by overhigh temperature of the exchange equipment during work due to overheating of parts in the machine body to a certain extent, adjusts the power of a fan according to actual temperature, effectively avoids energy waste and saves energy.

In order to achieve the purpose, the technical scheme is as follows:

an energy-saving communication exchange device comprises a base and a machine body arranged above the base;

the machine body is arranged on the mounting plate, and through holes penetrating to the lower part of the mounting plate are formed in the mounting plate;

a plurality of radiating pipes which are distributed at equal intervals are fixed in the through hole, the upper surface of each radiating pipe is attached to the lower surface of the machine body, and the radiating pipes are used for radiating the bottom surface of the machine body;

a circulating assembly is arranged above the machine body and used for cooling the cooling liquid in the radiating pipe;

the left end of the upper surface of the base is connected with a left plate, and two fans are embedded and installed on the right surface of the left plate and used for radiating heat of the machine body;

the right-hand member is connected with the electrostatic absorption board above the base, the electrostatic absorption board is used for adsorbing the dust.

Preferably, a filter plate is embedded into the left surface of the left plate and communicated with the fan.

Preferably, the radiating pipe is connected with a first radiating plate below, a plurality of capillaries distributed at equal intervals are arranged in the first radiating plate, and the upper ends of the capillaries are communicated with the lower end of the radiating pipe.

Preferably, the circulation assembly comprises a second heat dissipation plate, a condensation box, a water outlet pipe and a water inlet pipe, a cavity is formed in the second heat dissipation plate, the condensation box and the second heat dissipation plate are respectively installed on the left side and the right side above the machine body, and the left end of the second heat dissipation plate is communicated with the right end of the condensation box.

Preferably, the outlet pipe is equipped with a plurality of roots and is located the organism right side, the cooling tube right-hand member runs through out the mounting panel, a plurality of the outlet pipe lower extreme and a plurality of the cooling tube right-hand member intercommunication, the outlet pipe upper end with two right-hand members of heating panel intercommunication, the inlet tube is located the organism left side, the inlet tube upper end with the condensation box left end intercommunication, inlet branch pipe is installed in the inside left end embedding of mounting panel, the inlet tube lower extreme inserts the mounting panel inside and communicate with each other with inlet branch pipe, a plurality of the cooling tube left end with inlet branch pipe intercommunication, inlet tube externally mounted has the check valve.

Preferably, a temperature detector and a PLC are sequentially installed inside the machine body from left to right, and the temperature detector and the fan are electrically connected with the PLC.

The utility model has the beneficial effects that: the heat dissipation pipe is filled with cooling liquid to carry out better cooling and heat dissipation on the lower surface of the machine body, the heat dissipation effect of the cooling liquid is ensured through the circulating assembly, the problem that energy consumption is increased due to overhigh temperature of exchange equipment when in work due to overheating of components inside the machine body is avoided to a certain extent, the temperature detector is set with a highest temperature and a constant temperature, the highest temperature is the highest temperature for maintaining efficient operation of the machine body components, the constant temperature is the highest temperature for achieving the most efficient operation of the machine body components, when the temperature detector detects that the temperature inside the machine body exceeds the highest temperature, the temperature detector can transmit signals to the PLC controller, the PLC controller can control the fan to increase power, so that the heat dissipation efficiency of the machine body is accelerated, when the temperature detector detects that the temperature inside the machine body is lower than the constant temperature, the temperature detector can transmit signals to the PLC controller, the PLC controller can control the fan to reduce power, so that the heat dissipation efficiency of the machine body is reduced, the waste of energy caused by the fact that the fan dissipates heat to the machine body with the same power all the time is avoided, and energy is saved.

Drawings

FIG. 1 is a schematic overall perspective view of the present invention;

FIG. 2 is a schematic view of the overall front cross-sectional structure of the present invention;

FIG. 3 is an enlarged partial structural view of part A of FIG. 2 according to the present invention;

fig. 4 is a schematic diagram of a partial enlarged structure B of fig. 2 according to the present invention.

The labels in the figure are: the air conditioner comprises a base 101, a mounting plate 102, a first heat dissipation plate 103, a support column 104, an electrostatic adsorption plate 105, a left plate 106, a filter plate 107, a fan 108, a temperature detector 109, a machine body 110, a PLC 111, a second heat dissipation plate 112, a condensation box 113, a water outlet pipe 114, a water inlet pipe 115, a one-way valve 116, a water inlet branch pipe 117, a heat dissipation pipe 118 and a capillary pipe 119.

Detailed Description

As shown in fig. 1 to 4, the present application is an energy-saving communication exchange device, including a base 101 and a body 110 installed above the base 101, a mounting plate 102 is arranged above the base 101, supporting columns 104 are connected between four corners below the mounting plate 102 and the upper surface of the base 101, the body 110 is mounted on the mounting plate 102, a through hole penetrating to the lower surface of the mounting plate 102 is formed on the mounting plate 102, a plurality of radiating pipes 118 are fixed in the through holes and distributed at equal intervals, the upper surface of each radiating pipe 118 is attached to the lower surface of the machine body 110, the radiating pipes 118 are used for radiating the bottom surface of the machine body 110, the cooling pipe 118 is filled with the cooling fluid, the cooling fluid inside the cooling pipe 118 can effectively cool the bottom surface of the machine body 110, therefore, the machine body 110 is cooled and radiated, and the increase of energy consumption caused by overhigh temperature of the exchange equipment during work due to overheating of components in the machine body 110 is avoided to a certain extent;

the machine body 110 is provided with a circulating assembly above, the circulating assembly is used for cooling the cooling liquid inside the radiating pipe 118, a first radiating plate 103 is connected below the radiating pipe 118, a plurality of capillaries 119 distributed at equal intervals are arranged inside the first radiating plate 103, the upper end of the capillary 119 is communicated with the lower end of the radiating pipe 118, the circulating assembly comprises a second radiating plate 112, a condensing box 113, a water outlet pipe 114 and a water inlet pipe 115, a cavity is formed inside the second radiating plate 112, the condensing box 113 and the second radiating plate 112 are respectively arranged at the left side and the right side above the machine body 110, the left end of the second radiating plate 112 is communicated with the right end of the condensing box 113, the water outlet pipe 114 is provided with a plurality of pipes and is positioned at the right side of the machine body 110, the right end of the radiating pipe 118 penetrates through the mounting plate 102, the lower ends of the water outlet pipes 114 are communicated with the right ends of the radiating pipe 118, the upper end of the water outlet pipe 114 is communicated with the right ends of the second radiating plate 112, the inlet pipe 115 is located at the left side of the machine body 110, the upper end of the inlet pipe 115 is communicated with the left end of the condensation box 113, the left end of the interior of the mounting plate 102 is embedded with a water inlet branch pipe 117, the lower end of the inlet pipe 115 is inserted into the interior of the mounting plate 102 and is communicated with the water inlet branch pipe 117, the left ends of the plurality of radiating pipes 118 are communicated with the water inlet branch pipe 117, a check valve 116 is installed outside the inlet pipe 115, the coolant which absorbs heat in the radiating pipes 118 is evaporated to flow upwards after the temperature of the coolant rises, due to the check valve 116 installed outside the inlet pipe 115, a user can ensure that the flow direction of the inlet pipe 115 is from top to bottom when installing the check valve 116 outside the inlet pipe 115, the coolant in the radiating pipes 118 can flow upwards through the outlet pipe 114, the coolant which flows upwards can enter the second radiating plate 112 through the outlet pipe 114, and the first radiating plate 112 and the first radiating plate 103 both adopt materials with high heat radiation property, for example, special ceramics, the second heat dissipation plate 112 can exchange heat with air to dissipate the heat inside the cooling liquid, so that the cooling liquid is condensed to reduce the temperature of the cooling liquid, the condensed cooling liquid can enter the interior of the condensation box 113, the cooling liquid entering the interior of the condensation box 113 can flow into the water inlet branch pipe 117 through the water inlet pipe 115, the cooling liquid flowing into the water inlet branch pipe 117 can flow back to the heat dissipation pipe 118 again, thereby completing the circulation of the cooling liquid, ensuring that the heat dissipation pipe 118 can continuously dissipate heat of the machine body 110, and ensuring the heat dissipation effect of the machine body 110;

the left end of the upper surface of the base 101 is connected with a left plate 106, two fans 108 are embedded in the right surface of the left plate 106, the fans 108 are used for dissipating heat of a machine body 110, a filter plate 107 is embedded in the left surface of the left plate 106, the filter plate 107 is communicated with the fans 108, a temperature detector 109 and a PLC (programmable logic controller) 111 are sequentially installed in the machine body 110 from left to right, the temperature detector 109 and the fans 108 are electrically connected with the PLC 111, the fans 108 are positioned on the left side of the machine body 110 and are electrified, the fans 108 can blow wind to the right on the machine body 110 and a second radiating plate 112 and a first radiating plate 103 which are positioned on the upper side and the lower side of the machine body 110, the wind blown by the fans 108 can accelerate the heat dissipation of the second radiating plate 112 and the first radiating plate 103, the first radiating plate 103 is provided with a plurality of capillary tubes 119 which are distributed at equal intervals and respectively connected below a plurality of radiating tubes 118, the upper end of the capillary tube 119 is communicated with the lower end of the radiating tube 118, so that the cooling liquid in the radiating tube 118 can flow into the capillary tube 119, the heat dissipation on the surface of the first radiating plate 103 can be accelerated when wind blown by the fan 108 blows on the first radiating plate 103, the heat dissipation on the surface of the first radiating plate 103 can be accelerated to cool the cooling liquid in the capillary tube 119 of the first radiating plate 103, and meanwhile, the fan 108 can also accelerate the condensation of the cooling liquid in the second radiating plate 112 well, so that the cooling efficiency of the cooling liquid is effectively improved, because the temperature detector 109 is arranged in the machine body 110, the temperature detector 109 can detect the temperature in the machine body 110, a maximum temperature and a constant temperature are set for the temperature detector 109, the maximum temperature is the maximum temperature for maintaining the efficient operation of the machine body 110, and the constant temperature is the maximum temperature for achieving the most efficient operation of the machine body 110, when the temperature detector 109 detects that the temperature inside the machine body 110 exceeds the maximum temperature, the temperature detector 109 can transmit a signal to the PLC controller 111, the PLC controller 111 can control the fan 108 to improve the power, so that the heat dissipation efficiency of the machine body 110 is accelerated, when the temperature detector 109 detects that the temperature inside the machine body 110 is lower than the constant temperature, the temperature detector 109 can transmit the signal to the PLC controller 111, the PLC controller 111 can control the fan 108 to reduce the power, so that the heat dissipation efficiency of the machine body 110 is reduced, the waste of energy caused by the fact that the fan 108 dissipates heat to the machine body 110 with the same power all the time is avoided, and energy is saved;

the right-hand member is connected with electrostatic adsorption board 105 above base 101, electrostatic adsorption board 105 is used for adsorbing the dust, because the filter plate 107 rather than communicating inside is installed to fan 108 left end, so dust in the air that fan 108 inhaled alright effectively by filter plate 107 filter the absorption, effectively reduced the dust in the wind that fan 108 blew out, the wind that fan 108 blew out also can blow the dust on organism 110 surface right, the dust is blown right and can be adsorbed by electrostatic adsorption board 105, thereby the dust on organism 110 surface has been reduced to a certain extent, the effectual heat dissipation that has avoided the dust on organism 110 surface to influence communication exchange equipment, thereby further avoided the inside part of organism 110 overheated lead to exchange equipment during operation high temperature to lead to the power consumption to increase.

Claims (6)

1. An energy-saving communication exchange device, comprising a base (101) and a body (110) mounted above the base (101), characterized in that:

a mounting plate (102) is arranged above the base (101), supporting columns (104) are connected between four corners below the mounting plate (102) and the upper surface of the base (101), the machine body (110) is mounted on the mounting plate (102), and through holes penetrating to the lower surface of the mounting plate (102) are formed in the upper surface of the mounting plate (102);

a plurality of radiating pipes (118) which are distributed at equal intervals are fixed in the through holes, the upper surfaces of the radiating pipes (118) are attached to the lower surface of the machine body (110), and the radiating pipes (118) are used for radiating the bottom surface of the machine body (110);

a circulating assembly is arranged above the machine body (110) and used for cooling the cooling liquid in the radiating pipe (118);

the left end of the upper surface of the base (101) is connected with a left plate (106), two fans (108) are embedded in the right surface of the left plate (106), and the fans (108) are used for dissipating heat of the machine body (110);

the right-hand member is connected with electrostatic absorption board (105) above base (101), electrostatic absorption board (105) are used for adsorbing the dust.

2. A power efficient communication switching device as defined in claim 1, wherein: a filter plate (107) is embedded in the left surface of the left plate (106), and the filter plate (107) is communicated with a fan (108).

3. A power efficient communication switching device as defined in claim 1, wherein: the radiating pipe is characterized in that a first radiating plate (103) is connected below the radiating pipe (118), a plurality of capillaries (119) distributed at equal intervals are arranged inside the first radiating plate (103), and the upper ends of the capillaries (119) are communicated with the lower end of the radiating pipe (118).

4. A power efficient communication switching device as defined in claim 1, wherein: the circulating assembly comprises a second heat dissipation plate (112), a condensation box (113), a water outlet pipe (114) and a water inlet pipe (115), a cavity is formed in the second heat dissipation plate (112), the condensation box (113) and the second heat dissipation plate (112) are respectively installed on the left side and the right side above the machine body (110), and the left end of the second heat dissipation plate (112) is communicated with the right end of the condensation box (113).

5. An energy efficient communication switching apparatus as defined in claim 4, wherein: outlet pipe (114) is equipped with a plurality of roots and is located organism (110) right side, mounting panel (102), a plurality of run through out cooling tube (118) right-hand member outlet pipe (114) lower extreme and a plurality of roots cooling tube (118) right-hand member intercommunication, outlet pipe (114) upper end with heating panel two (112) right-hand member intercommunication, inlet tube (115) are located organism (110) left side, inlet tube (115) upper end with condenser box (113) left end intercommunication, inlet branch pipe (117) are installed in the inside left end embedding of mounting panel (102), inlet tube (115) lower extreme inserts mounting panel (102) inside and with inlet branch pipe (117) communicate with each other, a plurality of cooling tube (118) left end with inlet branch pipe (117) intercommunication, inlet tube (115) externally mounted has check valve (116).

6. A power efficient communication switching device as defined in claim 1, wherein: temperature detector (109) and PLC controller (111) are installed from a left side to the right side in proper order to organism (110) inside, temperature detector (109) and fan (108) and PLC controller (111) electric connection.

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