CN210776537U - Big data server heat dissipation cabinet - Google Patents

Abstract

The utility model provides a big data server heat dissipation cabinet. This big data server heat dissipation cabinet includes: a heat dissipation cabinet body; the host machine protection shell is fixedly arranged in the heat dissipation cabinet body and connected with the bottom surface of the heat dissipation cabinet body, wherein a gap is reserved between the heat dissipation cabinet body and the host machine protection shell; the fan mechanism penetrates through the side wall of the heat dissipation cabinet body; the first air dispersing channel is arranged at the bottom end of the side wall of the heat dissipating cabinet body; the baffle mechanism comprises an expansion spring fixedly arranged on the bottom surface of the heat dissipation cabinet body and a sealing baffle connected to the end part of the expansion spring and respectively abutted against the side walls of the heat dissipation cabinet body and the host machine protection shell; wherein, under the spring balanced state, the sealing baffle is connected with the first air-dispersing channel in a propping manner. The utility model provides a big data server heat dissipation cabinet can reduce wear.

Description

Big data server heat dissipation cabinet

Technical Field

The utility model relates to a server technical field, more specifically say, relate to a big data server heat dissipation cabinet.

Background

Servers, also known as servers, are often used to provide computing services. Specifically, the server needs to respond to and process the service request, and thus, a general server has service and guarantee service capabilities. The server contains a processor, a hard disk, a memory and other structures for providing high-reliability services, so that the requirements on the processing capability, stability, reliability, safety and the like of the server are high.

Compared with a common server, the large data server has higher integration level of internal structures so as to provide super computing capacity and storage capacity, and therefore, the requirements on the stability, reliability, safety and the like of the large data server are higher. When the large data server is used, the large data server generally needs to be installed in a special protection cabinet, however, the large data server is high in integration level and long in operation time, so that the heat productivity is high, and a special heat dissipation cabinet needs to be used for heat dissipation treatment. The conventional heat dissipation cabinet mostly dissipates heat through the opening and closing cabinet body. Specifically, as shown in fig. 1, the heat dissipation cabinet of the big data server includes a bottom plate 1, a top plate 2, a fixed plate 3, a movable plate 4, a threaded rod 5, and a servo motor 6. The working process is as follows: when the heat dissipation is not needed, the lower end of the moving plate 4 abuts against the bottom plate 1, the upper end of the fixed plate 3 abuts against the lower part of the top plate 2, and the moving plate serves as a normal server shell to bear a big data server. When heat dissipation is needed, the servo motor 6 is controlled to rotate, so that the servo motor 6 drives the threaded rod 5 to rotate, the threaded rod 5 and a nut (not marked in fig. 1) in the fixed plate 3 form a screw rod structure, the top plate 2 moves upwards, the top plate 2 drives the movable plate 4 to move upwards, an empty opening is formed between the movable plate 4 and the bottom plate 1 and between the fixed plate 3 and the top plate 2, and heat dissipation performance of the heat dissipation cabinet is enhanced.

However, the heat dissipation cabinet of the big data server needs to be opened and closed for multiple times to dissipate heat, and the heat dissipation cabinet is seriously worn due to multiple use, so that the heat dissipation function of the heat dissipation cabinet is affected.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a technical scheme of big data server heat dissipation cabinet to need the cabinet body that opens and shuts many times when solving the heat dissipation cabinet heat dissipation in the prior art structure that introduces in the background art, lead to cabinet body wearing and tearing serious, influence heat dissipation function problem.

In order to solve the technical problem, the utility model provides a following technical scheme:

the utility model provides a big data server heat dissipation cabinet, include: a heat dissipation cabinet body; the host machine protection shell is fixedly arranged in the heat dissipation cabinet body and connected with the bottom surface of the heat dissipation cabinet body, wherein a gap is reserved between the heat dissipation cabinet body and the host machine protection shell; the fan mechanism penetrates through the side wall of the heat dissipation cabinet body; the first air dissipation channel is arranged at the bottom end of the side wall of the heat dissipation cabinet body; the baffle mechanism is fixedly arranged on the bottom surface of the heat dissipation cabinet body and comprises an expansion spring fixedly arranged on the bottom surface of the heat dissipation cabinet body and a sealing baffle plate connected to the end part of the expansion spring and respectively abutted against the side walls of the heat dissipation cabinet body and the host machine protection shell; and under the balance state of the telescopic spring, the sealing baffle is abutted with the first air dispersing channel.

Preferably, in the big data server heat dissipation cabinet, the fan mechanism includes: the blower penetrates through the side wall of the heat dissipation cabinet body; the refrigerator is connected with the air outlet of the blower; and the temperature sensor is fixedly arranged on the side wall of the host protection shell and is electrically connected with the refrigerator.

Preferably, the big data server heat dissipation cabinet further comprises an air circulation mechanism, the air circulation mechanism comprising: and the air guide grooves are fixedly arranged on the outer side wall of the host protection shell and are triangular.

Preferably, the big data server heat dissipation cabinet further comprises: and the cold air drying mechanism is connected to the outer side wall of the host protective shell and is internally provided with a drying agent.

Preferably, the big data server heat dissipation cabinet further comprises: the closed cavity is fixedly arranged between the inner side wall and the outer side wall of the upper part of the heat dissipation cabinet body; the oxygen-free air bag is connected in the closed cavity and filled with high-pressure oxygen-free gas; and the ventilation pipeline is communicated with the oxygen-free air bag and extends into the host protective shell.

Preferably, the big data server heat dissipation cabinet further comprises: the opening and closing through hole is connected to the side wall of the host protective shell; the opening and closing through hole is communicated with the lower cavity of the sealing baffle; and the second air dispersing channel is arranged at the bottom end of the side wall of the heat dissipation cabinet body and is positioned below the first air dispersing channel, and the second air dispersing channel is abutted to the sealing baffle plate in a state of balance of the telescopic spring.

Preferably, the big data server heat dissipation cabinet further comprises: the gas purification bag is fixedly arranged at the upper end of the heat dissipation cabinet body and is communicated with the oxygen-free air bag; and the oxygen-free gas circulation pipeline is fixedly arranged on the outer wall of the heat dissipation cabinet body and is respectively communicated with the second air dissipation channel and the gas purification bag.

Preferably, the big data server heat dissipation cabinet further comprises: the circuit channel is dug on the bottom surface of the host protection shell and the bottom surface of the heat dissipation cabinet body; and a rubber sealing ring fixedly arranged on the line channel.

Preferably, the big data server heat dissipation cabinet further comprises: the air guide groove sliding rail is connected to the side wall of the host protective shell; the air guide groove slide rail is also connected with the plurality of air guide grooves in a sliding manner.

The technical scheme of the utility model the big data server heat dissipation cabinet that provides, the working process is as follows:

in the technical scheme, a host protection shell is fixedly arranged in the heat dissipation cabinet, and a big data server is arranged in the host protection shell. The fan mechanism penetrates through the side wall of the heat dissipation cabinet body, can supply air to the heat dissipation cabinet body, and causes air circulation flowing between the heat dissipation cabinet body and the host protection shell, so that heat is taken away through the air circulation flowing, and the temperature in the host protection shell is reduced through heat conduction. Because the baffle mechanism is arranged on the bottom surface of the heat dissipation cabinet body, when the fan mechanism conveys a large amount of air into the heat dissipation cabinet body, the air extrudes the sealing baffle in the baffle mechanism; the sealing baffle is extruded, and a first air dispersing channel which is originally in a balanced state and is abutted against the sealing baffle is exposed, so that the first air dispersing channel is communicated with the internal and external environments of the heat dissipation cabinet body, and air in the heat dissipation cabinet body is discharged; similarly, when the temperature in the heat dissipation cabinet body is too high, the air expands when heated, and the sealing baffle plate can be extruded, so that the air with partial heat is discharged out of the heat dissipation cabinet body. When part of air is discharged, the sealing baffle moves upwards under the action of the elastic force of the spring, so that the sealing baffle abuts against the first air dispersing channel again. The above process is repeated to achieve the purpose of heat dissipation.

The technical scheme of the big data server heat dissipation cabinet provided by the utility model, air is blown into the heat dissipation cabinet body through the fan mechanism, and the air extrudes the sealing baffle plate in the baffle plate mechanism, so that the air with partial heat can be discharged from the first air dissipation channel, thereby achieving the purpose of heat dissipation; when the air is exhausted, the expansion spring is restored to the balance state, and the sealing baffle plate is abutted against the first air dispersing channel again. The heat dissipation purpose is achieved by repeating the process. The utility model provides a big data server heat dissipation cabinet radiating mode is simple, through first scattered wind passageway exhaust air, need not the cabinet body that opens and shuts many times to can avoid traditional heat dissipation cabinet to need the serious wearing and tearing that the cabinet body that opens and shuts many times could dispel the heat and bring.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly described below, and it is obvious for those skilled in the art to obtain other drawings without inventive exercise.

FIG. 1 is a schematic diagram of a heat dissipation cabinet of a big data server provided in the prior art;

fig. 2 is a schematic structural diagram of a large data server heat dissipation cabinet according to an embodiment of the present invention.

In the embodiment shown in fig. 1 to 2, the correspondence between the structures and the reference numerals is as follows:

1-bottom plate, 2-top plate, 3-fixed plate, 4-moving plate, 5-threaded rod, 6-servo motor, 7-heat dissipation cabinet, 8-host protection shell, 9-fan mechanism, 91-blower, 92-refrigerator, 93-temperature sensor, 10-first air dispersing channel, 11-baffle mechanism, 111-expansion spring, 112-sealing baffle, 12-air circulation mechanism, 121-air guide groove, 122-air guide groove slide rail, 13-cold air drying mechanism, 14-sealing chamber, 15-oxygen-free air bag, 16-ventilation pipeline, 17-opening and closing through hole, 18-second air dispersing channel, 19-gas purification bag, 20-oxygen-free gas circulation pipeline, 21-circuit channel, etc, 22-rubber seal ring.

Detailed Description

The embodiment of the utility model provides a structural schematic diagram of big data server heat dissipation cabinet that shows has solved the problem that the heat dissipation cabinet wearing and tearing are serious that the cabinet body just can dispel the heat and lead to of needs that traditional heat dissipation cabinet exists many times among the prior art introduced in the background art.

In order to make those skilled in the art better understand the technical solution of the embodiments of the present invention and make the above objects, features and advantages of the embodiments of the present invention more obvious and understandable, the following description of the technical solution of the embodiments of the present invention will be made in detail with reference to the accompanying drawings.

Referring to fig. 2, fig. 2 is a schematic structural diagram of a large data server heat dissipation cabinet according to an embodiment of the present invention. As shown in fig. 2, the big data server heat dissipation cabinet includes:

a heat dissipation cabinet body 7;

and a host protection shell 8 fixedly arranged in the heat dissipation cabinet body 7 and connected with the bottom surface of the heat dissipation cabinet body 7, wherein a gap is reserved between the heat dissipation cabinet body 7 and the host protection shell 8.

The big data server is arranged in the host protection shell 8, and is protected through the host protection shell 8.

A fan mechanism 9 arranged on the side wall of the heat dissipation cabinet body 7 in a penetrating way; a first air-dispersing channel 10 arranged at the bottom end of the side wall of the heat-dispersing cabinet body 7.

The baffle mechanism 11 is fixedly arranged on the bottom surface of the heat dissipation cabinet 7, and the baffle mechanism 11 includes an expansion spring 111 fixedly arranged on the bottom surface of the heat dissipation cabinet 7, and a sealing baffle 112 connected to the upper end of the expansion spring 111 and respectively abutted against the side walls of the heat dissipation cabinet 7 and the host protection casing 8.

Wherein, under the balanced state of the extension spring 111, the sealing baffle plate 112 is abutted with the first air dispersing channel 10. The equilibrium state is a state in which the expansion spring 111 is in equilibrium with the weight of the seal retainer 112, the frictional force of the side wall, and the elastic force of the expansion spring 111.

The technical scheme of the utility model the big data server heat dissipation cabinet that provides, the working process is as follows:

in the big data server heat dissipation cabinet that this embodiment provided, set firmly host computer protection casing 8 in the heat dissipation cabinet body 7, be equipped with big data server in host computer protection casing 8. Wherein, fan mechanism 9 wears to locate the lateral wall of the heat dissipation cabinet body 7, can supply air to the internal 7 interior of heat dissipation cabinet, causes the air circulation flow between the heat dissipation cabinet body 7 and the host computer protection casing 8 to take away the heat through the air circulation flow, and then reduce the temperature in the host computer protection casing 8 through heat-conduction. Because the baffle mechanism 11 is arranged on the bottom surface of the heat dissipation cabinet body 7, when the fan mechanism 9 conveys a large amount of air into the heat dissipation cabinet body 7, the air extrudes the sealing baffle 112 in the baffle mechanism 11; by squeezing the sealing baffle 112, the first air-dispersing channel 10, which is originally in a state that the spring is in a balanced state and is abutted against the sealing baffle 112, is exposed, and the first air-dispersing channel 10 is communicated with the internal and external environments of the heat-dissipating cabinet body 7, so that the air in the heat-dissipating cabinet body 7 is discharged; also, when the temperature in the heat dissipating cabinet 7 is too high, the air expands due to heat and will press the sealing baffle 112, so that the air with partial heat is discharged out of the heat dissipating cabinet 7. When a part of the air is discharged, the sealing flap 112 is moved upward by the spring force to abut the first air dispersing channel 10 again. The above process is repeated to achieve the purpose of heat dissipation.

In the heat dissipation cabinet for the big data server provided by this embodiment, air is blown into the heat dissipation cabinet body 7 through the fan mechanism 9, and the air presses the sealing baffle 112 in the baffle mechanism 11, so that the air with partial heat can be discharged from the first air dissipation channel 10, thereby achieving the purpose of heat dissipation; when the air is exhausted, the expansion spring 111 returns to the equilibrium state, and the sealing baffle 112 will abut against the first air dispersing channel 10 again. The heat dissipation purpose is achieved by repeating the process. The utility model provides a big data server heat dissipation cabinet radiating mode is simple, through first wind passageway 10 exhaust air that looses, need not the cabinet body that opens and shuts many times to can avoid traditional heat dissipation cabinet to need the cabinet body that opens and shuts many times just can dispel the heat the serious wearing and tearing that bring.

In the big data server heat dissipation cabinet that this embodiment provided, through the circulation of the air between the heat dissipation cabinet body 7 and the host computer protection casing 8, and then realize the heat exchange between the heat dissipation cabinet body 7 and the host computer protection casing 8 through heat-conduction to reach the heat dissipation purpose. As shown in fig. 2 in detail, the blower mechanism 9 in this embodiment includes:

a blower 91 penetrating the side wall of the heat dissipating cabinet 7;

a refrigerator 92 connected to an air outlet of the blower 91;

and a temperature sensor 93 fixedly arranged on the side wall of the host machine protective shell 8, wherein the temperature sensor 93 is electrically connected with the refrigerator 92.

In the big data server heat dissipation cabinet provided in this embodiment, the blower 91 penetrating through the side wall of the heat dissipation cabinet 7 compresses the outside air, blows the compressed air into the heat dissipation cabinet 7, and cools the inflowing air by the refrigerator 92 connected to the air outlet of the blower 91, thereby reducing the temperature of the air between the heat dissipation cabinet 7 and the host protection casing 8; and through the heat conduction between the air inside and outside the host computer protection shell 8, reduce the temperature in the host computer protection shell 8 to reach the radiating purpose to big data server. In addition, the fan mechanism 9 can be isolated from the big data server by arranging the host protection shell 8, so that the big data server is prevented from being infected by sundries such as moisture and the like conveyed by the fan mechanism 9 and influencing the processing function of the big data server. Moreover, by fixedly arranging the temperature sensor 93 on the side wall of the host protection casing 8, the refrigeration function of the refrigerator 92 can be switched on and off according to the detected temperature near the host protection casing 8, so as to adjust the temperature in the big data server heat dissipation cabinet 7. The temperature sensor 93 may be disposed on an inner side wall of the main unit protection housing 8.

If the air blown by the fan mechanism 9 directly flows out from the lower first air dispersing channel 10, the heat exchange efficiency is not high. In order to improve the heat exchange efficiency and increase the number of air circulation times in the heat dissipation cabinet 7, as a preferred embodiment, as shown in fig. 2, the large data server heat dissipation cabinet in this embodiment further includes an air circulation mechanism 12, and the air circulation mechanism 12 includes:

and the air guide grooves 121 are fixedly arranged on the outer side wall of the host protection shell 8, and the air guide grooves 121 are triangular.

In the big data server heat dissipation cabinet that this embodiment provided, set firmly a plurality of wind-guiding grooves 121 through the lateral wall at host computer protection casing 8, when fan mechanism 9 blows, guide through wind-guiding grooves 121, the air will be fast flow between the inside wall of the heat dissipation cabinet body 7 and the lateral wall of host computer protection casing 8, and through the reflection of sealed baffle 112 and heat dissipation cabinet top surface, a lot of reciprocating cycle, thereby make the cold air can fully contact with host computer protection casing 8, and then take away the heat that big data server gived off in the host computer protection casing 8 through heat-conduction.

Moreover, in order to accurately guide the flow direction of the air in the heat dissipation cabinet 7, the heat dissipation cabinet of the big data server in this embodiment further includes: an air guide groove slide rail 122 connected to the side wall of the host protection casing 8; air guide channel slide rail 122 is also slidably coupled to plurality of air guide channels 121.

In this embodiment, by providing the air guide groove slide rail 122, the air guide groove 121 can slide along the side wall of the host protection casing 8, so as to adjust the circulation flow condition of the air in the heat dissipation cabinet 7, thereby further improving the heat dissipation efficiency of the environment in the host protection casing 8.

Because the air sent by the fan mechanism 9 may contain a large amount of water vapor, the water may be condensed and condensed on the outer side wall of the host protection casing 8 to form water drops, and then the water drops may penetrate into the host protection casing 8, so that the function of the big data server is reduced. In order to reduce this situation, as shown in fig. 2, as a preferred embodiment, the big data server heat dissipation cabinet in this embodiment further includes: and the cold air drying mechanism 13 is connected to the outer side wall of the host protection shell 8, wherein a drying agent is contained in the cold air drying mechanism 13.

In the big data server heat dissipation cabinet that this embodiment provided, cold wind drying mechanism 13 is connected in the lateral wall of host computer protection casing 8 to built-in drier can dry the air that fan mechanism 9 insufflates, and then reduces condensing of vapor on the host computer protection casing 8, protects big data server's in the host computer protection casing 8 normal operating.

When the big data server is operated in a charged mode, electric sparks can be generated, and if the big data server is in an oxygen-filled environment, a fire disaster can be easily caused. To avoid this situation, as shown in fig. 2, the large data server heat dissipation cabinet in this embodiment further includes, in addition to the above-mentioned structure:

a closed chamber 14 fixedly arranged between the inner side wall and the outer side wall of the upper part of the heat dissipation cabinet body 7;

an oxygen-free air bag 15 connected in the closed chamber 14, wherein the oxygen-free air bag 15 is filled with high-pressure oxygen-free gas; and the vent pipeline 16 is communicated with the oxygen-free air bag 15 and extends into the host protective shell 8.

The big data server heat dissipation cabinet of this embodiment, through set up airtight cavity 14 in the interior outer wall intermediate layer on heat dissipation cabinet body 7 upper portion to set up anaerobic gasbag 15 in airtight cavity 14, this anaerobic gasbag 15 is filled with high-pressure anaerobic gas, because the pressure of gasbag, through stretching into the vent pipe 16 in the host computer protection casing 8, can send into high-pressure anaerobic air in the host computer protection casing 8, in order to keep the inside anaerobic environment that is of host computer protection casing 8, and then avoid big data server to produce the electric spark and meet oxygen and arouse the conflagration. Wherein the oxygen-free air in the oxygen-free bladder 15 may be filled with carbon dioxide or inert gas, etc.

In order to discharge the unnecessary air in the host computer protection casing 8 equally, as shown in fig. 2, the embodiment of the utility model provides a big data server heat dissipation cabinet still includes:

an opening and closing through hole 17 connected to the side wall of the host protection casing 8;

the opening and closing through hole 17 is communicated with the lower cavity of the sealing baffle plate 112;

and a second air dispersing channel 18 which is arranged at the bottom end of the side wall of the heat dissipating cabinet body 7 and is positioned below the first air dispersing channel 10, wherein the second air dispersing channel 18 is abutted with the sealing baffle 112.

In the big data server heat dissipation cabinet of the embodiment, the opening and closing through hole 17 communicated with the cavity at the lower part of the sealing baffle 112 is arranged, so that the oxygen-free gas in the host protection shell 8 can be discharged into the cavity at the lower part of the sealing baffle 112, the sealing baffle 112 is extruded upwards to move upwards, and when the sealing baffle 112 moves upwards, the second air dissipation channel 18 is exposed, so that the oxygen-free gas in the host protection shell 8 is discharged out of the big data server heat dissipation cabinet; wherein the sealing baffle 112 is still in abutment with the first air dispersion channel 10 when the oxygen-free gas is discharged through the second air dispersion channel 18. The expansion spring 111 is in a balanced state, because the sealing baffle plate 112 is abutted with the second air dispersing channel 18, after the oxygen-free gas is discharged, the sealing baffle plate 112 retracts downwards due to the elastic force of the expansion spring 111, and is abutted with the second air dispersing channel 18 again.

In order to realize the recycling of the oxygen-free gas and maintain the high pressure state of the oxygen-free air bag 15, as shown in fig. 2, the large data server heat dissipation cabinet in this embodiment further includes:

a gas purification bag 19 fixedly arranged at the upper end of the heat dissipation cabinet body 7 and communicated with the oxygen-free air bag 15; and an oxygen-free gas circulation pipeline 20 fixedly arranged on the outer wall of the heat dissipation cabinet body 7 and respectively communicated with the second air dissipation channel 18 and the gas purification bag 19.

In the large data server heat dissipation cabinet of this embodiment, the oxygen-free gas circulation pipeline 20 is connected to the second air dissipation channel 18, so that the oxygen-free gas discharged from the heat dissipation cabinet is collected into the gas purification bag 19, and the oxygen-free gas flows into the oxygen-free air bag 15 again through the purification of the gas purification bag 19, thereby realizing the recycling of the oxygen-free gas, maintaining the high-pressure state of the oxygen-free air bag 15, and maintaining the oxygen-free environment in the host protection housing 8.

Because a big data server is arranged in the host protection shell 8 and is connected with the outside through a line, if the host protection shell 8 is not tightly sealed, gas in the host protection shell 8 may leak or oxygen-containing air may enter. In order to ensure that the lines are normally connected to the outside and the host computer is kept in an oxygen-free environment inside the host computer protection casing 8, as shown in fig. 2, the large data server heat dissipation cabinet in this embodiment further includes:

a circuit channel 21 dug on the bottom surface of the host protective shell 8 and the bottom surface of the heat dissipation cabinet 7; and a rubber packing 22 fixedly installed at the line passage 21.

In this big data server heat dissipation cabinet of implementing, dig through the bottom surface at host computer protection casing 8 and the heat dissipation cabinet body 7 and establish line passageway 21, can make things convenient for the circuit that the server extends and the external connection of big data server heat dissipation cabinet to through the sealed route passageway 21 of sealing washer 22, can keep host computer protection casing 8 airtight, thereby keep the inside anaerobic environment of host computer protection casing 8.

The technical scheme of the big data server heat dissipation cabinet provided by the utility model, air is blown into the heat dissipation cabinet body 7 through the fan mechanism 9, the air extrudes the sealing baffle plate 112 in the baffle plate mechanism 11, and the air with partial heat can be discharged from the first air dissipation channel 10, thereby achieving the purpose of heat dissipation; when the air is exhausted, the expansion spring 111 returns to the equilibrium state, and the sealing baffle 112 will abut against the first air dispersing channel 10 again. The heat dissipation purpose is achieved by repeating the process. The utility model provides a big data server heat dissipation cabinet radiating mode is simple, through first wind passageway 10 exhaust air that looses, need not the cabinet body that opens and shuts many times to can avoid traditional heat dissipation cabinet to need the cabinet body that opens and shuts many times just can dispel the heat the serious wearing and tearing that bring.

The same and similar parts among the various embodiments in this specification are referred to each other, and each embodiment focuses on differences from the other embodiments.

The above-mentioned embodiments of the present invention do not limit the scope of the present invention. Any modification, equivalent replacement, and improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (9)

1. A big data server heat dissipation cabinet, comprising:

a heat dissipation cabinet body (7);

a host protection shell (8) fixedly arranged in the heat dissipation cabinet body (7) and connected with the bottom surface of the heat dissipation cabinet body (7), wherein a gap is reserved between the heat dissipation cabinet body (7) and the host protection shell (8);

the fan mechanism (9) penetrates through the side wall of the heat dissipation cabinet body (7);

the first air dispersing channel (10) is arranged at the bottom end of the side wall of the heat dissipating cabinet body (7);

the baffle mechanism (11) is fixedly arranged on the bottom surface of the heat dissipation cabinet body (7), and the baffle mechanism (11) comprises a telescopic spring (111) fixedly arranged on the bottom surface of the heat dissipation cabinet body (7) and a sealing baffle (112) which is connected to the end part of the telescopic spring (111) and is respectively abutted against the side walls of the heat dissipation cabinet body (7) and the host machine protection shell (8);

wherein, under the balanced state of the telescopic spring (111), the sealing baffle (112) is abutted with the first air dispersing channel (10).

2. A big data server heat sink cabinet according to claim 1, wherein the fan mechanism (9) comprises:

the blower (91) penetrates through the side wall of the heat dissipation cabinet body (7);

a refrigerator (92) connected to an air outlet of the blower (91);

and the temperature sensor (93) is fixedly arranged on the side wall of the host machine protection shell (8), and the temperature sensor (93) is electrically connected with the refrigerator (92).

3. A big data server heat dissipation cabinet according to claim 1 or 2, further comprising an air circulation mechanism (12), the air circulation mechanism (12) comprising:

the air guide grooves (121) are fixedly arranged on the outer side wall of the host protection shell (8), and the air guide grooves (121) are triangular.

4. The big data server heat sink cabinet of claim 1, further comprising:

and the cold air drying mechanism (13) is connected to the outer side wall of the host protection shell (8), and a drying agent is contained in the cold air drying mechanism (13).

5. The big data server heat sink cabinet of claim 1, further comprising:

a closed chamber (14) fixedly arranged between the inner side wall and the outer side wall of the upper part of the heat dissipation cabinet body (7);

an oxygen-free air bag (15) connected in the closed chamber (14), wherein the oxygen-free air bag (15) is filled with high-pressure oxygen-free gas;

and the ventilation pipeline (16) is communicated with the oxygen-free air bag (15) and extends into the host protection shell (8).

6. The big data server heat sink cabinet of claim 5, further comprising:

an opening and closing through hole (17) connected to the side wall of the host protection shell (8); the opening and closing through hole (17) is communicated with a lower cavity of the sealing baffle plate (112);

and the second air dispersing channel (18) is arranged at the bottom end of the side wall of the heat dissipation cabinet body (7) and is positioned below the first air dispersing channel (10), wherein the second air dispersing channel (18) is abutted to the sealing baffle (112) in the balanced state of the telescopic spring (111).

7. The big data server heat sink cabinet of claim 6, further comprising:

a gas purification bag (19) fixedly arranged at the upper end of the heat dissipation cabinet body (7) and communicated with the oxygen-free air bag (15);

and the oxygen-free gas circulation pipeline (20) is fixedly arranged on the outer wall of the heat dissipation cabinet body (7) and is respectively communicated with the second air dissipation channel (18) and the gas purification bag (19).

8. The big data server heat sink cabinet of claim 1, further comprising:

a circuit channel (21) dug in the bottom surface of the host protective shell (8) and the bottom surface of the heat dissipation cabinet body (7); and the number of the first and second groups,

and the rubber sealing ring (22) is fixedly arranged in the circuit channel (21).

9. A big data server heat sink cabinet according to claim 3, wherein the air circulation mechanism (12) further comprises: the air guide groove sliding rail (122) is connected to the side wall of the host protection shell (8); the air guide groove slide rail (122) is also connected with the plurality of air guide grooves (121) in a sliding manner.

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