CN212460500U

CN212460500U - Server cooling device

Info

Publication number: CN212460500U
Application number: CN202021559800.4U
Authority: CN
Inventors: 丁勇
Original assignee: Nanjing Polytechnic Institute
Current assignee: Nanjing Polytechnic Institute
Priority date: 2020-07-31
Filing date: 2020-07-31
Publication date: 2021-02-02
Anticipated expiration: 2030-07-31

Abstract

Server heat sink, including first box, supply socket, controller, compressor, condenser, fin, drying filter, capillary, left evaporator assembly, right evaporator assembly, fretwork baffle, second box, fan, temperature sensor, sliding door, louvre and temperature regulation knob, supply socket is installed outward to first box, and supply socket wire connection installs the controller, and the compressor is installed in the controller wire connection. The utility model has the advantages that: the initial adjustment temperature is set, and the adjustment can be carried out according to the environmental temperature so as to achieve the optimal cooling effect; the heat dissipation condition of the server is monitored in real time through the temperature sensor, so that the overheating and supercooling conditions are avoided, and the server is always in a constant temperature environment; a vapor compression type refrigerating system is adopted, a compressor, a condenser, a capillary tube, an evaporator and the like are connected into a sealing system by PPR pipelines, so that the refrigerating area is increased, and the refrigerating effect is improved; low cost and more convenient later maintenance.

Description

Server cooling device

Technical Field

The utility model relates to a server heat sink belongs to server technical field.

Background

The server operating at the highest speed generates a large amount of heat, and particularly under the condition that the ambient temperature is increased in summer, the heat dissipation problem of the server is more difficult to solve. Overheating of the server can cause the system to crash down suddenly, with immeasurable consequences. The traditional air cooling is more and more unconscious, and how to realize the rapid cooling of the server is a problem to be solved.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a server heat sink.

The to-be-solved problem of the utility model is that the existing server cooling method adopts air cooling, and the cooling and heat dissipation effect is unsatisfactory.

For realizing the purpose of the utility model, the utility model adopts the technical proposal that:

a server cooling device comprises a first box body, a power socket, a controller, a compressor, a condenser, radiating fins, a drying filter, capillary tubes, a left evaporator assembly, a right evaporator assembly, a hollowed-out partition plate, a second box body, a fan, a temperature sensor, a sliding door, radiating holes and a temperature adjusting knob, wherein the power socket is installed outside the first box body, the controller is installed through a power socket lead in a connecting mode, the compressor is installed through a controller lead in a connecting mode, the condenser is installed through a compressor tail-end spiral assembly in a connecting mode, the radiating fins are additionally installed on a pipeline of the condenser, the drying filter is installed through a pipeline output end in a connecting mode, the capillary tubes are installed through a drying filter tail end in a connecting mode, the left evaporator assembly is installed through a capillary tube tail end in a connecting mode, the right, install the fretwork baffle on the compressor, install the second box on the fretwork baffle, the fan is installed on second box top, and second box back mounted has temperature sensor, has seted up the sliding door before the second box, and the first box left and right sides is equipped with the louvre, and temperature regulation knob is installed to first box front end.

Furthermore, the compressor, the condenser, the drying filter, the capillary tube, the left evaporator assembly and the right evaporator assembly are connected into a sealing system through pipelines, and the pipelines are connected through PPR pipelines, so that the cost is low, and the installation is convenient.

Further, the temperature adjusting knob is connected with the controller through a wire, the temperature sensor is connected with the controller through a wire, and the condenser is fixedly installed on the outer wall of the back of the device to accelerate heat dissipation.

The utility model has the advantages that: by setting the initial regulation temperature, the real-time temperature regulation can be carried out according to the environmental temperature so as to achieve the optimal cooling effect; the heat dissipation condition of the server is monitored in real time through the temperature sensor, so that the overheating and supercooling conditions are avoided, and the server is always in a constant temperature environment; a vapor compression type refrigerating system is adopted, a compressor, a condenser, a capillary tube, an evaporator and the like are connected into a sealing system by PPR pipelines, so that the refrigerating area is increased, and the refrigerating effect is improved; low cost and convenient later maintenance and replacement.

Drawings

FIG. 1 is a schematic diagram of the internal structure of a server cooling device;

FIG. 2 is a schematic diagram of the overall structure of the server cooling device;

in the figure: 1. the device comprises a first box body 2, a power socket 3, a controller 4, a compressor 5, a condenser 6, a radiating fin 7, a drying filter 8, a capillary tube 9, a left evaporator assembly 10, a right evaporator assembly 11, a hollow partition plate 12, a second box body 13, a fan 14, a temperature sensor 15, a sliding door 16, a radiating hole 17 and a temperature adjusting knob.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and examples.

A server cooling device comprises a first box body 1, a power socket 2, a controller 3, a compressor 4, a condenser 5, a cooling fin 6, a drying filter 7, a capillary tube 8, a left evaporator assembly 9, a right evaporator assembly 10, a hollow partition 11, a second box body 12, a fan 13, a temperature sensor 14, a sliding door 15, a cooling hole 16 and a temperature adjusting knob 17, wherein the power socket 2 is installed outside the first box body 1 and used for being connected with a power supply, the controller 3 is installed on the power socket 2 in a wire connection mode and used for processing and outputting data signals, the compressor 4 is installed on the controller 3 in a wire connection mode and used for absorbing steam, the condenser 5 is installed on a spiral assembly at the tail end of the compressor 4 in a wire connection mode and used for absorbing high-temperature and high-pressure gas and cooling, the cooling fin 6 is additionally installed on a pipeline of the condenser 5 and used for, used for drying and filtering, the tail end of the drying filter 7 is connected with and provided with a capillary tube 8 used for throttling and pressure reduction, the tail end of the capillary tube 8 is connected with and provided with a left evaporator component 9, the tail end of the left evaporator component 9 is connected with a right evaporator component 10 for absorbing heat, the tail end of the right evaporator component 10 is connected with a compressor 4, the compressor 4 is provided with a hollow clapboard 11, the hollow clapboard 11 is provided with a second box body 12 which is a container part and is used for air circulation, the top end of the second box body 12 is provided with a fan 13, used for accelerating air circulation, a temperature sensor 14 is arranged on the back of the second box body 12 and used for collecting data signals, a sliding door 15 is arranged in front of the second box body 12, the temperature adjusting device is used for opening a door, heat dissipation holes 16 are formed in the left side and the right side of the first box body 1 and used for dissipating heat, and a temperature adjusting knob 17 is installed at the front end of the first box body 1 and used for setting initial temperature.

Furthermore, the compressor 4, the condenser 5, the drying filter 7, the capillary tube 8, the left evaporator assembly 9 and the right evaporator assembly 10 are connected into a sealed system through pipelines, and the pipelines are connected through PPR pipelines, so that the cost is low, and the installation is convenient.

Further, the temperature adjusting knob 17 is connected with the controller 3 through a lead, the temperature sensor 14 is connected with the controller 3 through a lead, and the condenser 5 is fixedly installed on the outer wall of the back of the device to accelerate heat dissipation.

The using method comprises the following steps: the power socket 2 is connected with a power supply, the temperature adjusting knob 17 is rotated to set the temperature, the fan 13 works to accelerate the air flow in the second box 12, the temperature sensor 14 collects a temperature signal and transmits the temperature signal to the controller 3, the controller 3 processes a data signal, when the temperature in the second box 12 reaches a preset value, the controller 3 controls the compressor 4 to start working, refrigerant liquid exchanges heat with a server in the second box 12 at a low temperature in the left evaporator assembly 9 and the right evaporator assembly 10 to absorb heat generated by the server and gasify, generated low-pressure steam is sucked by the compressor 4 and is discharged at a high pressure after being compressed, high-pressure gas refrigerant discharged by the compressor 4 enters the condenser 5 and is cooled by air at normal temperature and condensed into high-pressure liquid, the heat dissipation area is increased by the radiating fins 6 additionally arranged on the pipeline of the condenser 5 in the condensation process, the heat is accelerated to be dissipated into the surrounding air, the high-pressure liquid is dried and impurity-removed when flowing through the drying filter 7, throttled when flowing through the capillary tube 8, changed into a low-pressure and low-temperature gas-liquid two-phase mixture, and enters the left evaporator assembly 9 and the right evaporator assembly 10 again for evaporation refrigeration, and the generated low-pressure steam is sucked by the compressor 4 again, and the process is repeated in cycles and is circulated continuously; when the temperature signal collected by the temperature sensor 14 is lower than the preset temperature value, the controller 3 processes the data signal and controls the compressor 4 to stop working and stop absorbing steam.

Claims

1. Server heat sink, including first box (1), supply socket (2), controller (3), compressor (4), condenser (5), fin (6), drier-filter (7), capillary (8), left evaporator assembly (9), right evaporator assembly (10), fretwork baffle (11), second box (12), fan (13), temperature sensor (14), sliding door (15), louvre (16) and temperature regulation knob (17), characterized by: a power socket (2) is installed outside the first box body (1), a controller (3) is installed on the power socket (2) through wire connection, a compressor (4) is installed on the controller (3) through wire connection, a condenser (5) is installed at the tail end of the compressor (4) through connection of a spiral component, radiating fins (6) are additionally installed on a pipeline of the condenser (5), a drying filter (7) is installed at the pipeline output end of the condenser (5), a capillary tube (8) is installed at the tail end of the drying filter (7), a left evaporator component (9) is installed at the tail end of the capillary tube (8), a right evaporator component (10) is installed at the tail end of the left evaporator component (9), the compressor (4) is installed at the tail end of the right evaporator component (10), a hollow partition plate (11) is installed on the compressor (4), and a second box body, the fan (13) is installed on the top end of the second box body (12), the temperature sensor (14) is installed on the back face of the second box body (12), the sliding door (15) is arranged in front of the second box body (12), the heat dissipation holes (16) are formed in the left side and the right side of the first box body (1), and the temperature adjusting knob (17) is installed at the front end of the first box body (1).

2. The server cooling device according to claim 1, wherein: the compressor (4), the condenser (5), the drying filter (7), the capillary tube (8), the left evaporator assembly (9) and the right evaporator assembly (10) are connected into a sealing system through pipelines, and the pipelines are connected through PPR pipelines, so that the cost is low, and the installation is convenient.

3. The server cooling device according to claim 1, wherein: temperature regulation knob (17) link to each other with controller (3) through the wire, and temperature sensor (14) link to each other with controller (3) through the wire, and condenser (5) fixed mounting is on device back outer wall, dispels the heat with higher speed.