CN115038295A - Server electric appliance cabinet for big data storage and control method - Google Patents

Abstract

The invention relates to the technical field of big data retrieval, in particular to a server electric appliance cabinet for big data storage and a control method. The invention provides a server electric appliance cabinet for big data storage, which comprises: the device comprises a constant temperature box, a supporting platform, a linkage part and two heat dissipation boxes; two sides of the thermostat are respectively provided with a heat exchange fan, and one heat exchange fan corresponds to one heat dissipation box; a heat dissipation chamber is arranged in the heat dissipation box; the heat dissipation box is at least internally provided with a water bin chamber, and cooling water is injected into the water bin chamber; the upper end of the heat dissipation box is hinged with a cover plate, and the cover plate seals the heat dissipation chamber and the water chamber; when the linkage part drives the heat dissipation box to move towards any heat exchange fan, a groove is formed on the advancing direction side of the heat dissipation box; when the linkage part moves reversely, the airflow in the groove is driven to flow towards the heat exchange fan; when the temperature in the constant temperature box is too high, the cover plate flaps the heat exchange fan; when the water in the water bin overflows into the heat dissipation bin, the heat of the heat dissipation agent absorbs heat to cool the interior of the constant temperature box.

Description

Server electric appliance cabinet for big data storage and control method

Technical Field

The invention relates to the technical field of big data retrieval, in particular to a server electric appliance cabinet for big data storage and a control method.

Background

In the installation process of electrical equipment, more and more motor control cabinets are installed on site, but because the environment of industrial field is different, some environment can be very high in temperature, and the operation of equipment can be influenced to the high temperature in the server use. Among the prior art many through water-cooling or air-cooled mode cool off the thermostatic control cabinet to guarantee the normal work of server, but the radiating effect after the forced air cooling is too high to the temperature in the equipment is not good, and the water-cooling is installed again and is used complicacy, still needs extra refrigeration cycle water, and equipment operation cost is high.

Therefore, it is necessary to develop a server electrical cabinet for large data storage.

Disclosure of Invention

The invention aims to provide a server electric appliance cabinet for big data storage.

In order to solve the above technical problem, the present invention provides a server electrical cabinet for big data storage, including: the device comprises a thermostat, a supporting table, a linkage part and two heat dissipation boxes, wherein the thermostat is rectangular, the thermostat is hollow, a partition plate is fixed in the thermostat, the supporting table is fixed on one side of the partition plate, and the supporting table is suitable for a server;

two sides of the constant temperature box are respectively provided with a heat exchange fan, and one heat exchange fan corresponds to one heat dissipation box;

the linkage part is arranged on the other side of the partition plate in a reciprocating sliding manner, and the two heat dissipation boxes are respectively fixed at two ends of the linkage part;

the heat dissipation box is rectangular, the heat dissipation box is hollow, a heat dissipation chamber is arranged in the heat dissipation box, granular heat dissipation agents are arranged in the heat dissipation chamber, two side walls of the heat dissipation chamber are flexible films, and the flexible films are parallel to the heat exchange fan;

the heat dissipation box is internally provided with at least one water bin chamber, and cooling water is injected into the water bin chamber;

the upper end of the heat dissipation box is hinged with a cover plate, one end of the cover plate is clamped and inserted at the upper end of the heat dissipation box, and the cover plate seals the heat dissipation chamber and the water chamber; wherein

When the linkage part drives the heat dissipation box to move towards any direction of the heat exchange fan, the heat dissipation agent extrudes the flexible film to deform, so that a groove is formed on the advancing direction side of the heat dissipation box;

when the linkage part moves reversely, the heat radiating agent extrudes the flexible film under the action of inertia to drive the airflow in the groove to flow towards the heat exchange fan;

when the temperature in the constant temperature box is overhigh, the temperature in the water bin rises to cause the pressure in the water bin to rise so as to open the cover plate, and when the linkage part drives the heat dissipation box to move to the maximum stroke, the cover plate flaps the heat exchange fan;

when water in the water bin overflows into the heat dissipation bin, the water reacts with the heat dissipation agent, and the heat dissipation agent absorbs heat to cool the interior of the constant temperature box.

Furthermore, the cover plate is hinged to the upper end of the heat dissipation box through a torsion spring, an annular hand buckle is fixed on the cover plate, and the lower end of the annular hand buckle is matched with the side wall of the heat dissipation chamber; wherein

When the cover plate is covered, the annular hand buckle can tightly buckle and seal the cover plate at the upper end of the heat dissipation chamber;

when the pressure in the water bin rises, the cover plate can be pushed by the pressure to separate the annular hand buckle from the heat dissipation bin;

the linkage part drives the annular hand buckle to horizontally slide and flap the heat exchange fan to warn that the temperature in the constant temperature box is too high.

Furthermore, the outer wall of the heat dissipation chamber is provided with a step matched with the annular hand buckle, the step is parallel to the inner wall of the lower end of the annular hand buckle, and when the cover is closed, the lower end of the annular hand buckle can be inserted into the lower end face of the step to seal the water chamber and the heat dissipation chamber.

Further, the linkage portion includes: the driving motor is fixed in the constant temperature box, the reciprocating moving assembly can be arranged on the side wall of the partition plate in a reciprocating sliding mode, and the two heat dissipation boxes are respectively fixed at two ends of the reciprocating moving assembly;

the axial rotating assembly is rotatably arranged on the side wall of the reciprocating moving assembly and is matched with the reciprocating moving assembly;

the axial rotating assembly is in transmission connection with the driving motor; wherein

During operation, driving motor drive axial rotating assembly intermittent type nature just reverse to make reciprocating motion subassembly is followed the baffle horizontal reciprocating sliding.

Further, the axial rotation assembly includes: the upper rotating fluted disc and the lower rotating fluted disc are oppositely arranged and are respectively fixed at two ends of the fixed column, and the fixed column, the upper rotating fluted disc and the lower rotating fluted disc are concentrically arranged;

a linkage disc is rotatably arranged between the upper rotary fluted disc and the lower rotary fluted disc, the linkage disc is sleeved at the end part of a conveying shaft of the driving motor, and the linkage disc is meshed with the upper rotary fluted disc and the lower rotary fluted disc; wherein

When the linkage disc is meshed with the upper rotary fluted disc, the linkage disc can drive the upper rotary fluted disc to rotate clockwise;

when the linkage disk is meshed with the lower rotary fluted disc, the linkage disk can drive the upper rotary fluted disc to rotate anticlockwise.

Furthermore, a conical surface is arranged on one side, close to the upper rotating fluted disc, of the linkage disc, and a plurality of racks matched with the upper rotating fluted disc or the lower rotating fluted disc are fixed on the conical surface; wherein

When the linkage disc axially rotates, the rack is intermittently meshed with the upper rotating fluted disc or the lower rotating fluted disc, so that the fixed column is driven to rotate clockwise or anticlockwise.

Further, the rack ring the setting of linkage dish circumference, just the circular arc section of rack is not more than the quarter of linkage dish circumference.

Further, the shuttle assembly includes: the fixing plate is fixed on one side, far away from the supporting table, of the partition plate;

the side wall of the fixed plate is provided with a sliding chute matched with the sliding linear tooth, the sliding linear tooth is arranged in the sliding chute in a sliding way, and the two heat dissipation boxes are respectively fixed at two ends of the sliding linear tooth;

the fixed block is vertically fixed at the upper end of the fixed plate, the threaded rotating shaft is rotatably arranged at the lower end of the fixed block, and the threaded rotating shaft is meshed with the sliding linear teeth;

the threaded rotating shaft is fixed at the upper end of the upper rotary fluted disc and is concentrically arranged with the fixed column; wherein

When the threaded rotating shaft rotates clockwise, the threaded rotating shaft drives the sliding linear teeth to horizontally slide rightwards;

when the threaded rotating shaft rotates anticlockwise, the threaded rotating shaft drives the sliding linear teeth to horizontally slide leftwards.

Furthermore, a plurality of rollers are arranged at the bottom of the incubator, a supporting block is arranged on one side of each roller in a lifting mode, and when the supporting blocks rotate to descend, the lower ends of the supporting blocks abut against a horizontal plane so as to fixedly support the incubator.

Based on the technical scheme, the invention also provides a control method of the server electric appliance cabinet for big data storage, when the drive motor drives the linkage disk to axially rotate, the linkage disk drives the rack to synchronously axially rotate, when the linkage disk drives the rack to be meshed with the upper rotary fluted disc, the linkage disk can drive the upper rotary fluted disc to clockwise rotate, at the moment, the upper rotary fluted disc drives the threaded rotating shaft to synchronously clockwise rotate, and the threaded rotating shaft synchronously drives the sliding linear teeth to horizontally slide rightwards; when the linkage disc driving rack is meshed with the lower fluted disc, the linkage disc can drive the upper fluted disc to rotate anticlockwise, the upper fluted disc drives the threaded rotating shaft to synchronously rotate anticlockwise, and the threaded rotating shaft synchronously drives the sliding linear teeth to horizontally slide leftwards; in the process of driving the heat dissipation box to horizontally reciprocate leftwards and rightwards by the sliding linear teeth, the heat dissipation agent extrudes the flexible film to deform, a groove is formed in the advancing direction side of the heat dissipation box, and when the heat dissipation box moves in the reverse direction, the heat dissipation agent extrudes the flexible film under the action of inertia to drive airflow in the groove to flow towards the heat exchange fan so as to improve the air flow in the incubator.

The server electric appliance cabinet for storing the big data has the advantages that the server electric appliance cabinet for storing the big data can drive the two heat dissipation boxes to horizontally slide through the arrangement of the linkage part, so that the heat dissipation boxes can drive the hot air in the constant temperature box to be discharged outwards. Through the setting of heat dissipation box for when the temperature in the thermostated container is too big, can send the chimes of doom, and promptly cool down to the thermostated container.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a perspective view of a preferred embodiment of a server appliance cabinet for large data storage of the present invention;

FIG. 2 is a perspective view of the heat dissipation case of the present invention;

FIG. 3 is an internal schematic view of the present invention;

FIG. 4 is a perspective view of the linkage of the present invention;

fig. 5 is a perspective view of the axial rotation assembly of the present invention.

In the figure:

1. a thermostat; 11. a roller; 12. a support block; 13. a heat exchange fan; 2. a support table; 3. a linkage section; 31. a drive motor; 310. a linkage disk; 311. a rack; 32. a reciprocating assembly; 321. a fixing plate; 322. sliding the linear teeth; 323. a fixed block; 324. a threaded shaft;

33. an axial rotation assembly; 331. fixing a column; 332. an upper rotary fluted disc; 333. a lower fluted disc;

4. a heat dissipation box; 41. a heat dissipation chamber; 42. a water compartment; 43. a flexible film; 44. a cover plate; 45. an annular hand buckle; 46. and (4) a step.

Detailed Description

The present invention will now be described in further detail with reference to the accompanying drawings. These drawings are simplified schematic views illustrating only the basic structure of the present invention in a schematic manner, and thus show only the constitution related to the present invention.

As shown in fig. 1 to 5, the present invention provides a server electrical cabinet for big data storage, including: a constant temperature box 1, a support platform 2, a linkage part 3 and two heat dissipation boxes 4. The oven 1 is adapted to house and mount therein a support stand 2, a linkage portion 3 and two heat-dissipating boxes 4. The support table 2 is adapted to support a server. The linkage part 3 is suitable for driving the two heat dissipation boxes 4 to horizontally slide. The two heat dissipation boxes 4 are suitable for fanning the air in the incubator 1 to discharge outwards. With respect to the above components, detailed description will be made below.

Constant temperature box

Thermostat 1 sets up on the horizontal plane, and thermostat 1 is the rectangle, and thermostat 1 is inside cavity, is suitable for to place and install a supporting bench 2, linkage portion 3 and two heat dissipation boxes 4 in thermostat 1. Two sides of the incubator 1 are respectively provided with a heat exchange fan 13, and when the heat exchange fans 13 work, the air in the incubator 1 can be blown out. Be suitable for in thermostated container 1 to place the server, and thermostated container 1 is when using, for with external half isolated state, thermostated container 1 only has gas exchange with the external world to ensure that the server in thermostated container 1 can not be damaged by the dust or drenched by the water and cause the damage. In actual use, since the server is operated to generate heat, the heat exchange fan 13 can flare out the air in the incubator 1 to thereby flare out the hot air in the incubator 1 from the incubator 1, and at the same time, after the air pressure in the incubator 1 is reduced, the outside air can enter the incubator 1 through the heat exchange fan 13.

In addition, a plurality of rollers 11 are arranged at the bottom of the incubator 1, and when the rollers 11 contact with a horizontal plane, the incubator 1 can be driven to horizontally slide so as to change the position of the incubator 1. One side of each roller 11 is provided with a supporting block 12 in a lifting manner, when the supporting block 12 is rotated to descend, the lower end of the supporting block 12 is abutted against the horizontal plane so as to fixedly support the incubator 1.

Supporting table

Support bench 2 sets up in thermostated container 1, specifically, is provided with a baffle in the thermostated container 1, and support bench 2 sets up in baffle one side, is suitable for the support server on support bench 2.

Linkage part

The linkage part 3 is arranged in the incubator 1, and the linkage part 3 is arranged on the other side of the clapboard in a reciprocating sliding way. The linkage portion 3 is adapted to drive the two heat dissipation boxes 4 to horizontally slide, thereby blowing the hot air in the oven 1 to be discharged outward.

The following describes the structure of the interlocking section 3 specifically, and the interlocking section 3 includes: a drive motor 31, a reciprocating assembly 32 and an axial rotation assembly 33. The driving motor 31 is fixed in the incubator 1, and particularly, a vertical rod is arranged at the middle position of the incubator 1. The driving motor 31 is fixed on the vertical rod, and an output shaft of the driving motor 31 is horizontally arranged. The reciprocating component 32 is arranged on the side wall of the partition, and the reciprocating component 32 and the support platform 2 are arranged on two sides of the partition. The reciprocating assembly 32 can slide horizontally along the partition plate under the driving of the driving motor 31. The heat exchange fans 13 are disposed at both sides of the reciprocating assembly 32 in the length direction, and the reciprocating assembly 32 can be moved close to the two heat exchange fans 13 in a reciprocating manner in a horizontal movement process. The axial rotating component 33 is rotatably arranged on the side wall of the reciprocating component 32, and the axial rotating component 33 is matched with the reciprocating component 32. The axial rotation assembly 33 is in transmission connection with the driving motor 31, and specifically, the driving motor 31 can drive the axial rotation assembly 33 to intermittently switch bidirectional rotation. When the axial rotation assembly 33 rotates in both directions, the reciprocating assembly 32 can be driven to slide horizontally in the corresponding direction.

In order to achieve the above-mentioned effect that the driving motor 31 drives the axial rotation assembly 33 to intermittently rotate in two directions, the axial rotation assembly 33 includes: a fixed column 331, an upper fluted disc 332 and a lower fluted disc 333. The upper fluted disc 332 and the lower fluted disc 333 are arranged oppositely, the upper fluted disc 332 and the lower fluted disc 333 are fixed at two ends of the fixed column 331 respectively, and the fixed column 331, the upper fluted disc 332 and the lower fluted disc 333 are arranged concentrically. When the upper rotating toothed disc 332 rotates axially, the lower rotating toothed disc 333 can be driven to synchronously rotate axially through the fixed column 331; similarly, when the lower rotating toothed disc 333 rotates axially, the upper rotating toothed disc 332 can be driven to rotate axially synchronously by the fixing column 331. A linkage disk 310 is fixedly connected to the end of the rotating shaft of the driving motor 31, and the linkage disk 310 is rotatably disposed between the upper toothed disk 332 and the lower toothed disk 333. The driving motor 31 is coaxially arranged with the linkage disk 310, the linkage disk 310 is vertically arranged with the upper fluted disk 332 and the lower fluted disk 333, and an extension line of the axis of the linkage disk 310 passes through the axis of the upper fluted disk 332. A tapered surface is arranged on one side of the linkage disc 310 close to the upper toothed disc 332, a plurality of racks 311 matched with the upper toothed disc 332 or the lower toothed disc 333 are fixed on the tapered surface, and the racks 311 can be meshed with the upper toothed disc 332 or the lower toothed disc 333. When the driving motor 31 works, the linkage disc 310 can be driven to rotate anticlockwise continuously, and when the linkage disc 310 rotates until the rack 311 is meshed with the upper rotating fluted disc 332, the linkage disc 310 drives the upper rotating fluted disc to rotate clockwise; when the linkage plate 310 rotates until the rack 311 engages with the lower toothed plate 333, the linkage plate 310 drives the upper epicyclic toothed plate to rotate counterclockwise. In addition, in order to achieve the effect that the upper toothed disc 332 and the lower toothed disc 333 are driven by the linkage disk 310 to intermittently rotate, the number of the racks 311 does not exceed one fourth of the circumferential length of the linkage disk 310, and in this way, when the racks 311 are engaged with the upper toothed disc 332 and the lower toothed disc 333, the upper toothed disc 332 and the lower toothed disc 333 rotate clockwise or counterclockwise, and when the racks 311 are disengaged from the upper toothed disc 332 and the lower toothed disc 333, the upper toothed disc 332 and the lower toothed disc 333 do not rotate.

In order to realize the effect of driving the reciprocating assembly 32 to horizontally slide in the corresponding direction when the axial rotating assembly 33 rotates in both directions. The shuttle assembly 32 includes: a fixed plate 321, a sliding straight tooth 322, a fixed block 323 and a threaded rotating shaft 324. The fixing plate 321 is fixed on a side of the partition plate away from the supporting table 2. The side wall of the fixing plate 321 is provided with a sliding slot adapted to the sliding linear tooth 322, and the sliding linear tooth 322 is slidably disposed in the sliding slot. The fixing block 323 is vertically fixed at the upper end of the fixing plate 321, the threaded rotating shaft 324 is rotatably arranged at the lower end of the fixing block 323, the upper rotating disc is fixedly connected with the lower end of the threaded rotating shaft 324, and the threaded rotating shaft 324 and the fixing column 331 are concentrically arranged. When the upper rotating disk rotates clockwise or anticlockwise, the threaded rotating shaft 324 can be driven to synchronously rotate clockwise or anticlockwise. The threaded rotating shaft 324 is engaged with the sliding linear tooth 322, and when the threaded rotating shaft 324 rotates clockwise, the threaded rotating shaft 324 drives the sliding linear tooth 322 to horizontally slide rightwards; when the threaded rotating shaft 324 rotates counterclockwise, the threaded rotating shaft 324 drives the sliding linear tooth 322 to slide horizontally leftward.

Heat radiation box

Two heat dissipation boxes 4 are fixed respectively slide the both ends of linear tooth 322, one heat transfer fan 13 corresponds a heat dissipation box 4, and when slide linear tooth 322 was followed the horizontal slip, can drive heat dissipation box 4 and move the hot-air in 1 thermostated container to heat transfer fan 13 to when the temperature in 1 thermostated container was too big, can send the chimes of doom, and to 1 emergency cooling of thermostated container.

The structure of the heat dissipation box 4 is specifically described below, the heat dissipation box 4 is rectangular, and the interior of the heat dissipation box 4 is hollow. The inside of the heat dissipation box 4 is provided with a heat dissipation chamber 41, the inside of the heat dissipation chamber 41 is provided with a granular heat dissipation agent, in the embodiment, the preferable heat dissipation agent substance is ammonium nitrate powder, and after the ammonium nitrate powder contacts with water, the ammonium nitrate powder can react with the water, become a hard solid, and absorb heat. Two side walls of the heat dissipation chamber 41 are flexible films 43, and the flexible films 43 are parallel to the heat exchange fan 13. When the heat dissipation box 4 horizontally slides along with the sliding linear teeth 322, the heat dissipation box deforms along with the reverse direction of the horizontal sliding of the sliding linear teeth 322 to form a groove shape, the groove formed by the flexible film 43 contains hot air, and when the heat dissipation box 4 moves to the maximum stroke of the sliding linear teeth 322, the flexible film 43 is thrown outwards towards the heat exchange fan 13 under the action of inertia. At least one water chamber 42 is further disposed in the heat dissipation box 4, and the number of the water chambers 42 in this embodiment is preferably two, and the two water chambers 42 are disposed on two sides of the heat dissipation chamber 41 respectively. The water chamber 42 is filled with cooling water, and when the temperature in the incubator 1 rises, the cooling water can absorb heat. The upper end of the heat dissipation box 4 is hinged with a cover plate 44, the lower end of the cover plate 44 is provided with a convex block, and a groove matched with the convex block is arranged between the heat dissipation chamber 41 and the water chamber 42. One end of the cover plate 44 is inserted into the upper end of the heat dissipation box 4, and the cover plate 44 seals the heat dissipation chamber 41 and the water chamber 42. The apron 44 articulates through the torsional spring 4 upper ends dispel the heat, be fixed with an annular hand and detain 45 on the apron 44, annular hand detain 45 lower extreme with the lateral wall looks adaptation of heat dissipation bin 41, heat dissipation bin 41 outer wall be provided with one with the step 46 of annular hand knot 45 looks adaptation, the lower extreme inner wall that step 46 and annular hand detained 45 is parallel to each other, and when covering, the terminal surface can insert step 46 under the annular hand detains 45 lower extreme and closes water compartment 42 and heat dissipation bin 41 with sealed lid. When the cover plate 44 is closed, the annular hand buckle 45 can fasten and seal the cover plate 44 at the upper end of the heat dissipation chamber 41. When the temperature in the incubator 1 rises until the water in the water sump turns into vapor, the pressure in the water sump rises, and the cover plate 44 can be pushed by the pressure to separate the annular hand buckle 45 from the heat dissipation chamber 41. Annular hand buckle 45 is opened to when slip straight line tooth 322 drive annular hand buckle 45 horizontal slip to the biggest end of stroke, annular hand buckle 45 can offset with heat transfer fan 13, and pat heat transfer fan 13 in order to warn that the interior high temperature of thermostated container 1.

In addition, when the annular hand buckle 45 is opened, the corresponding bump and the corresponding groove on the cover plate 44 are separated, the cooling water in the water chamber 42 overflows and flows into the heat dissipation chamber 41, and the cooling water and the ammonium nitrate powder in the heat dissipation chamber 41 are mixed to react and absorb heat, so that the emergency cooling of the thermostat 1 is realized. Meanwhile, the alarm function of the annular hand buckle 45 is matched, so that an operator can be prompted to maintain the thermostat 1, the heat radiating agent in the heat radiating chamber 41 is replaced, and cooling water is added into the water chamber 42.

Example two

The second embodiment further provides a control method for a server electrical cabinet for big data storage based on the first embodiment, which includes the server electrical cabinet for big data storage according to the first embodiment, and the specific structure of the server electrical cabinet is the same as that of the first embodiment, and is not described herein again. The specific control method for the server electric appliance cabinet for big data storage is as follows:

when the driving motor 31 drives the linkage disc 310 to axially rotate, the linkage disc 310 drives the rack 311 to synchronously axially rotate, when the linkage disc 310 drives the rack 311 to mesh with the upper fluted disc 332, the linkage disc 310 can drive the upper fluted disc 332 to clockwise rotate, at this time, the upper fluted disc 332 drives the threaded rotating shaft 324 to synchronously clockwise rotate, and the threaded rotating shaft 324 synchronously drives the sliding linear teeth 322 to horizontally slide rightward; when the linkage disc 310 drives the rack 311 to be meshed with the lower toothed disc 333, the linkage disc 310 can drive the upper toothed disc 332 to rotate counterclockwise, at this time, the upper toothed disc 332 drives the threaded rotating shaft 324 to synchronously rotate counterclockwise, and the threaded rotating shaft 324 synchronously drives the sliding linear teeth 322 to horizontally slide leftward; in the process that the sliding linear teeth 322 drive the heat dissipation box 4 to horizontally reciprocate left and right, the heat dissipation agent extrudes the flexible film 43 to deform, a groove is formed in the advancing direction side of the heat dissipation box 4, and when the heat dissipation box 4 moves in the reverse direction, the heat dissipation agent extrudes the flexible film 43 under the action of inertia to drive the airflow in the groove to flow towards the heat exchange fan 13 so as to improve the air flow in the incubator 1.

In light of the foregoing description of the preferred embodiment of the present invention, it is intended that the present invention cover modifications and variations of this invention provided they fall within the scope of the following claims. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.

Claims (10)

1. A server electrical cabinet for big data storage, comprising:

the server comprises a thermostat (1), a supporting table (2), a linkage part (3) and two heat dissipation boxes (4), wherein the thermostat (1) is rectangular, the thermostat (1) is hollow, a partition plate is fixed in the thermostat (1), the supporting table (2) is fixed on one side of the partition plate, and the supporting table (2) is suitable for a server;

two sides of the constant temperature box (1) are respectively provided with a heat exchange fan (13), and one heat exchange fan (13) corresponds to one heat dissipation box (4);

the linkage part (3) is arranged on the other side of the partition plate in a reciprocating sliding manner, and the two heat dissipation boxes (4) are respectively fixed at two ends of the linkage part (3);

the heat dissipation box (4) is rectangular, the heat dissipation box (4) is hollow, a heat dissipation chamber (41) is arranged in the heat dissipation box (4), granular heat dissipation agents are arranged in the heat dissipation chamber (41), two side walls of the heat dissipation chamber (41) are flexible films (43), and the flexible films (43) are parallel to the heat exchange fan (13);

at least one water chamber (42) is arranged in the heat dissipation box (4), and cooling water is injected into the water chamber (42);

a cover plate (44) is hinged to the upper end of the heat dissipation box (4), one end of the cover plate (44) is clamped and inserted at the upper end of the heat dissipation box (4), and the cover plate (44) seals the heat dissipation chamber (41) and the water chamber (42); wherein

When the linkage part (3) drives the heat dissipation box (4) to move towards any heat exchange fan (13), the heat dissipation agent extrudes the flexible film (43) to deform, so that a groove is formed on the advancing direction side of the heat dissipation box (4);

when the linkage part (3) moves in the opposite direction, the heat radiating agent extrudes the flexible film (43) under the inertia effect to drive the airflow in the groove to flow towards the heat exchange fan (13);

when the temperature in the constant temperature box (1) is too high, the temperature in the water bin (42) rises to cause the pressure in the water bin (42) to rise, so that the cover plate (44) is opened, and when the linkage part (3) drives the heat dissipation box (4) to move to the maximum stroke, the cover plate (44) beats the heat exchange fan (13);

when the water in the water chamber (42) overflows into the heat dissipation chamber (41), the water reacts with the heat dissipation agent, and the heat dissipation agent absorbs heat to cool the interior of the constant temperature box (1).

2. The server electrical cabinet for big data storage according to claim 1,

the cover plate (44) is hinged to the upper end of the heat dissipation box (4) through a torsion spring, an annular hand buckle (45) is fixed on the cover plate (44), and the lower end of the annular hand buckle (45) is matched with the side wall of the heat dissipation chamber (41); wherein

When the cover plate (44) is covered, the annular hand buckle (45) can fasten and seal the cover plate (44) at the upper end of the heat dissipation chamber (41);

when the pressure in the water sump rises, the cover plate (44) can be pushed by the pressure to separate the annular hand buckle (45) from the heat dissipation chamber (41);

the linkage part (3) drives the annular hand buckle (45) to horizontally slide and flap the heat exchange fan to warn that the temperature in the constant temperature box (1) is too high.

3. The server electrical cabinet for big data storage according to claim 2,

the outer wall of the heat dissipation chamber (41) is provided with a step (46) matched with the annular hand buckle (45), the inner walls of the lower ends of the step (46) and the annular hand buckle (45) are parallel to each other, and when the cover is closed, the lower end of the annular hand buckle (45) can be inserted into the lower end face of the step (46) to seal the water chamber (42) and the heat dissipation chamber (41).

4. A server electric cabinet for big data storage according to claim 3,

the linkage portion (3) includes: the heat dissipation device comprises a driving motor (31), a reciprocating moving assembly (32) and an axial rotating assembly (33), wherein the driving motor (31) is fixed in the incubator (1), the reciprocating moving assembly (32) can be arranged on the side wall of the partition plate in a reciprocating sliding mode, and two heat dissipation boxes (4) are respectively fixed at two ends of the reciprocating moving assembly (32);

the axial rotating assembly (33) is rotatably arranged on the side wall of the reciprocating assembly (32), and the axial rotating assembly (33) is matched with the reciprocating assembly (32);

the axial rotating assembly (33) is in transmission connection with the driving motor (31); wherein

When the device works, the driving motor (31) drives the axial rotating assembly (33) to intermittently rotate positively and negatively so that the reciprocating moving assembly (32) horizontally slides in a reciprocating mode along the partition plate.

5. The server electrical cabinet for big data storage according to claim 4,

the axial rotation assembly (33) comprises: the fixing column (331), the upper rotating toothed disc (332) and the lower rotating toothed disc (333), wherein the upper rotating toothed disc (332) and the lower rotating toothed disc (333) are arranged oppositely, the upper rotating toothed disc (332) and the lower rotating toothed disc (333) are respectively fixed at two ends of the fixing column (331), and the fixing column (331), the upper rotating toothed disc (332) and the lower rotating toothed disc (333) are arranged concentrically;

a linkage disc (310) is rotatably arranged between the upper fluted disc (332) and the lower fluted disc (333), the linkage disc (310) is sleeved at the end part of a conveying shaft of the driving motor (31), and the linkage disc (310) is meshed with the upper fluted disc (332) and the lower fluted disc (333); wherein

When the linkage disc (310) is meshed with the upper rotating fluted disc (332), the linkage disc (310) can drive the upper rotating fluted disc (332) to rotate clockwise;

when the linkage disc (310) is meshed with the lower fluted disc (333), the linkage disc (310) can drive the upper fluted disc (332) to rotate anticlockwise.

6. The server electrical cabinet for big data storage according to claim 5,

a conical surface is arranged on one side, close to the upper rotating toothed disc (332), of the linkage disc (310), and a plurality of racks (311) matched with the upper rotating toothed disc (332) or the lower rotating toothed disc (333) are fixed on the conical surface; wherein

When the linkage disc (310) axially rotates, the rack (311) intermittently meshes with the upper rotating toothed disc (332) or the lower rotating toothed disc (333), so that the fixed column (331) is driven to rotate clockwise or anticlockwise.

7. The server electrical cabinet for big data storage according to claim 6,

the rack (311) is arranged around the circumference of the linkage disc (310), and the arc section of the rack (311) is not more than one fourth of the circumference of the linkage disc (310).

8. The server electrical cabinet for big data storage according to claim 7,

the shuttle assembly (32) comprises: the device comprises a fixing plate (321), sliding linear teeth (322), a fixing block (323) and a threaded rotating shaft (324), wherein the fixing plate (321) is fixed on one side, far away from the supporting platform (2), of the partition plate;

the side wall of the fixing plate (321) is provided with a sliding chute matched with the sliding linear tooth (322), the sliding linear tooth (322) is arranged in the sliding chute in a sliding manner, and the two heat dissipation boxes (4) are respectively fixed at two ends of the sliding linear tooth (322);

the fixed block (323) is vertically fixed at the upper end of the fixed plate (321), the threaded rotating shaft (324) is rotatably arranged at the lower end of the fixed block (323), and the threaded rotating shaft (324) is meshed with the sliding linear teeth (322);

the threaded rotating shaft (324) is fixed at the upper end of the upper rotating fluted disc (332), and the threaded rotating shaft (324) and the fixed column (331) are arranged concentrically; wherein

When the threaded rotating shaft (324) rotates clockwise, the threaded rotating shaft (324) drives the sliding linear teeth (322) to horizontally slide rightwards;

when the threaded rotating shaft (324) rotates anticlockwise, the threaded rotating shaft (324) drives the sliding linear tooth (322) to horizontally slide leftwards.

9. The server electrical cabinet for big data storage according to claim 8,

a plurality of rollers (11) are arranged at the bottom of the thermostat (1), a supporting block (12) is arranged on one side of each roller (11) in a lifting mode, and when the supporting block (12) descends, the lower end of the supporting block (12) abuts against a horizontal plane to fixedly support the thermostat (1).

10. A control method of a server electric cabinet for big data storage, which is characterized by comprising the server electric cabinet for big data storage according to claim 9,

when the driving motor (31) drives the linkage disc (310) to axially rotate, the linkage disc (310) drives the rack (311) to synchronously axially rotate, when the linkage disc (310) drives the rack (311) to be meshed with the upper rotating fluted disc (332), the linkage disc (310) can drive the upper rotating fluted disc (332) to clockwise rotate, at the moment, the upper rotating fluted disc (332) drives the threaded rotating shaft (324) to synchronously clockwise rotate, and the threaded rotating shaft (324) synchronously drives the sliding linear teeth (322) to horizontally slide rightwards; when the linkage disc (310) drives the rack (311) to be meshed with the lower fluted disc (333), the linkage disc (310) can drive the upper fluted disc (332) to rotate anticlockwise, at the moment, the upper fluted disc (332) drives the threaded rotating shaft (324) to synchronously rotate anticlockwise, and the threaded rotating shaft (324) synchronously drives the sliding linear teeth (322) to horizontally slide leftwards; in the process of driving the heat dissipation box (4) to horizontally reciprocate leftwards and rightwards by the sliding linear teeth (322), the heat dissipation agent extrudes the flexible film (43) to deform, a groove is formed in the advancing direction side of the heat dissipation box (4), and when the heat dissipation box (4) moves in the reverse direction, the heat dissipation agent extrudes the flexible film (43) under the action of inertia to drive airflow in the groove to gush towards the heat exchange fan (13) so as to improve the air flow in the constant temperature box (1).

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