CN112969348B - Acquisition method, system and equipment for computer big data processing - Google Patents

Abstract

The invention relates to a method, a system and equipment for acquiring big data processing of a computer, which comprises a heat exchange shell outside a computer seal; a vertical isolation inner cavity, a front process inner space and a module placing inner cavity for placing a computer component are arranged in the inner cavity of the heat exchange shell outside the computer seal; the vertical isolation inner cavity and the front technical space are positioned at the rear and front sides of the module placing inner cavity; the top wall of the module placing inner cavity is a shell closed cover; a water-blocking breathable net film is arranged on the heat exchange shell outside the computer seal, and the pore diameter of the water-blocking breathable net film is smaller than the diameter of water molecules; the bottom of the computer sealed outer heat exchange shell is provided with a bottom sliding seat, and the top of the computer sealed outer heat exchange shell is provided with a top guide rail; the invention has reasonable design, compact structure and convenient use.

Description

Acquisition method, system and equipment for computer big data processing

Technical Field

The invention relates to a method, a system, equipment and a medium for acquiring computer big data processing.

Background

The strategic significance of big data technology is not to grasp huge data information, but to specialize the data containing significance. In other words, if big data is compared to an industry, the key to realizing profitability in the industry is to improve the "processing ability" of the data and realize the "value-added" of the data through the "processing". Technically, the relation between big data and cloud computing is as inseparable as the front and back of a coin. The large data cannot be processed by a single computer necessarily, and a distributed architecture must be adopted. The method is characterized in that distributed data mining is carried out on mass data. But it must rely on distributed processing of cloud computing, distributed databases and cloud storage, virtualization technologies. With the advent of the cloud era, big data has attracted more and more attention. Analyst teams believe that large data is often used to describe the large amount of unstructured and semi-structured data created by a company that can take excessive time and money to download to a relational database for analysis. Big data analysis is often tied to cloud computing because real-time large dataset analysis requires a MapReduce-like framework to distribute work to tens, hundreds, or even thousands of computers.

Cn202010770957.x a method, system, device and medium for collecting big data of computer, which is an improved solution, but cannot solve the problem of storage in tens, hundreds or even thousands of computers, especially data storage devices, but cannot solve the problem of heat dissipation. Therefore, the method has multiple modes of air cooling, water cooling and the like, then, the air cooling is gradually replaced by the water cooling, and diversion type cold water is changed into immersion type water cooling, however, the immersion type water cooling has the problem that after a certain module of a computer is damaged, the water needs to be discharged, so that the whole unit stops working completely, and the collection and treatment efficiency is influenced.

Disclosure of Invention

The invention aims to solve the technical problem of providing a computer big data processing acquisition method, a computer big data processing acquisition system, computer big data processing equipment and a computer big data processing medium.

In order to solve the problems, the technical scheme adopted by the invention is as follows:

a computer processing system includes a computer sealed outer heat exchange housing;

a vertical isolation inner cavity, a front process inner space and a module placing inner cavity for placing a computer component are arranged in the inner cavity of the heat exchange shell outside the computer seal;

the vertical isolation inner cavity and the front technical space are positioned at the rear and front sides of the module placing inner cavity; the top wall of the module placing inner cavity is a shell closed cover;

a water-blocking breathable net film is arranged on the heat exchange shell outside the computer seal, and the pore diameter of the water-blocking breathable net film is smaller than the diameter of water molecules;

the bottom of the computer sealed outer heat exchange shell is provided with a bottom sliding seat, and the top of the computer sealed outer heat exchange shell is provided with a top guide rail;

when the computer sealed outer heat exchange shell is laminated, the bottom sliding seat of the upper computer sealed outer heat exchange shell slides on the top guide rail of the lower computer sealed outer heat exchange shell;

the front side surface of the space in the front process is provided with a front L-shaped channel with an opening at the upper end, a vertical process support is arranged in the vertical isolation inner cavity, the vertical process support is provided with a vertical lifting inner cavity in a hollow manner, the upper part of the vertical process support is provided with a vertical process top through hole, and the lower part of the vertical process support is provided with a vertical process bottom through hole which is coaxial with the vertical process top through hole; a vertical process eccentric opening is communicated with the side part of the vertical process top through hole and the vertical process bottom through hole;

a module transmission data wire of a computer component with the lower end and a module placing inner cavity is hermetically arranged on the computer sealed outer heat exchange shell; the upper end of the module transmission data line is provided with a data line joint exposed out of the water surface, and one side of the data line joint is provided with a joint process seat;

a herringbone opening of the joint is arranged on the cross arm of the joint craft seat;

a concentrator is arranged above the water surface and is electrically connected with the data line connector in an inserting mode;

a movable manipulator is arranged above the water surface, a first lifting outer jacking sleeve is vertically lifted at the movable end of the movable manipulator, a second lifting inner rotating lifting rod is arranged in the first lifting outer jacking sleeve in a lifting mode, a lower lifting arm is arranged at the lower end of the second lifting inner rotating lifting rod,

after the lower lifting arm sinks to pass through the herringbone opening of the joint, the lower lifting arm rotates to be in pressure contact with the lower surface of the joint process seat, and the first lifting outer jacking sleeve is in pressure contact with the upper surface of the joint process seat;

a third lifting line and a fourth L-shaped replacement arm are respectively arranged at the lower end of the mobile manipulator;

the lower end of the third lifting line is connected with a third L-shaped lifting arm;

a fourth L-shaped replacement arm enters along the front L-shaped groove in a moving mode, moves transversely and then rises, and a hook head of the fourth L-shaped replacement arm is located in the front process space to hook the computer sealing outer heat exchange shell to be replaced;

the third L-shaped lifting arm descends from the vertical process eccentric notch of the topmost computer sealed outer heat exchange shell to the upper layer of computer sealed outer heat exchange shell to be replaced and rotationally hooks the computer sealed outer heat exchange shell.

As a further improvement of the above technical solution:

a protective wire outer sleeve part is arranged on the computer sealed outer heat exchange shell in a sealing mode, and the module transmission data wire penetrates through the protective wire outer sleeve part in a sealing mode.

An acquisition device for computer big data processing comprises a computer storage grid assembly with an L-shaped baffle frame with an inclined plane; computer processing systems are stacked and stacked in the L-shaped baffle frame with the inclined plane;

the L-shaped baffle frame with the inclined plane is provided with a bottom inclined plane with the root part lower than the end part, a process longitudinal clearance guide rail is arranged between L-shaped baffle frame vertical plates with the inclined plane, and the L-shaped baffle frame vertical plates with the inclined plane are used for being in contact positioning with the rear side surface of the computer sealed outer heat exchange shell;

a lifting sliding rear push seat is lifted at the process longitudinal gap guide rail, and a process auxiliary outer push rod and a process auxiliary pull-back arm which are horizontally telescopic and distributed at high and low positions are arranged on the lifting sliding rear push seat;

the process auxiliary outer push rod is used for pushing out the rear side of the computer sealed outer heat exchange shell to be replaced;

the process auxiliary pull-back arm is used for hooking a process groove on the rear side of the computer sealed outer heat exchange shell of the lower layer to be replaced.

A computer big data processing acquisition system comprises a computer outer frame assembly and acquisition equipment in the water of the computer outer frame assembly;

the computer outer frame body assembly comprises an outer sealing shell;

an inner seal housing is disposed in the outer seal housing.

As a further improvement of the above technical solution:

a circulating pipeline communicated with the interlayer and a circulating pump connected with the circulating pipeline are respectively arranged on the outer sealing shell, and a thermometer is arranged on the outer sealing shell;

the interlayer of the outer sealed shell is filled with cooling liquid.

A computer big data processing acquisition method sequentially executes big data acquisition, processing calculation, storage and output through a computer component; when a computer component needs to be replaced, the following steps are performed,

s1, descending the third L-shaped lifting arm from the vertical process eccentric notch of the topmost computer sealed outer heat exchange shell to the next layer of computer sealed outer heat exchange shell to be replaced, and lifting the computer sealed outer heat exchange shell in a rotating and hooking manner to separate the bottom sliding seat from the top guide rail;

s2, pushing out the rear side of the computer sealed outer heat exchange shell to be replaced by the process auxiliary outer push rod, and hooking the process auxiliary pull-back arm in the process groove at the rear side of the computer sealed outer heat exchange shell at the lower layer to be replaced;

s3, enabling a fourth L-shaped replacement arm to enter along a front L-shaped groove and move transversely and then ascend, enabling a hook head of the fourth L-shaped replacement arm to be located in a front process space so as to hook a sealed outer heat exchange shell of the computer to be replaced, and enabling a bottom sliding seat to slide along a top guide rail;

and S4, lowering the computer sealing outer heat exchange shell of the previous layer to one layer.

The invention has the advantages of reasonable design, low cost, firmness, durability, safety, reliability, simple operation, time and labor saving, capital saving, compact structure and convenient use.

Drawings

Fig. 1 is a schematic diagram of the overall use structure of the invention.

Fig. 2 is a structural schematic diagram of the external sealing shell of the invention.

FIG. 3 is a schematic view of the bottom bevel configuration of the present invention.

Fig. 4 is a schematic structural diagram of the present invention.

FIG. 5 is a schematic diagram of the structure of the heat exchange housing outside the computer seal according to the present invention.

Fig. 6 is a schematic view of a first lifting outer top sleeve structure of the present invention.

Wherein: 1. A computer outer frame assembly; 2. a computer storing grid components; 3. an outer seal housing; 4. an inner sealed housing; 5. a circulation line; 6. a thermometer; 7. a circulation pump; 8. an L-shaped baffle frame with an inclined plane; 9. a bottom bevel; 10. a process longitudinal gap guide rail; 11. lifting and sliding the rear push seat; 12. a process auxiliary outer push rod; 13. a process-assisted pullback arm; 14. the computer is provided with an outer sealed heat exchange shell; 15. vertically isolating the inner cavity; 16. a module placement cavity; 17. a water-blocking breathable breathing net film; 18. a top rail; 19. a bottom slide carriage; 20. a front L-shaped channel; 21. a front intra-process space; 22. a housing closing cover; 23. a vertical process support; 24. a vertical process bottom through hole; 25. a vertical process top via; 26. vertical process eccentric gap; 27. vertically lifting the inner cavity; 28. the module transmits the data line; 29. a data line connector; 30. a joint process seat; 31. a herringbone opening is formed in the joint; 32. a protection wire jacket portion; 33. a hub; 34. moving the manipulator; 35. a first lifting outer top sleeve; 36. a second lifting internal rotating lifting rod; 37. a lower lifting arm; 38. a third lift wire; 39. a third L-shaped lifting arm; 40. and fourthly, replacing the arm in an L shape.

Detailed Description

As shown in FIGS. 1-6, the computer processing system of the present embodiment includes a computer sealed outer heat exchange housing 14;

a vertical isolation inner cavity 15, a front process inner space 21 and a module placing inner cavity 16 for placing computer components are arranged in the inner cavity of the computer sealed outer heat exchange shell 14;

the vertical isolation inner cavity 15 and the front technical inner space 21 are positioned at the rear and front sides of the module placing inner cavity 16; a shell sealing cover 22 is arranged on the top wall of the module placing inner cavity 16;

a water-blocking breathable net film 17 is arranged on the computer sealed outer heat exchange shell 14, and the aperture of the water-blocking breathable net film 17 is smaller than the diameter of water molecules;

a bottom sliding seat 19 is arranged at the bottom of the computer sealed outer heat exchange shell 14, and a top guide rail 18 is arranged at the top of the computer sealed outer heat exchange shell 14;

when the computer sealed outer heat exchange housings 14 are stacked, the bottom slide 19 of the upper computer sealed outer heat exchange housing 14 slides on the top rail 18 of the lower computer sealed outer heat exchange housing 14;

a front L-shaped channel 20 with an opening at the upper end is arranged on the front side surface of the front process space 21, a vertical process support 23 is arranged in the vertical isolation inner cavity 15, a vertical lifting inner cavity 27 is arranged in the vertical process support 23 in a hollow mode, a vertical process top through hole 25 is arranged at the upper part of the vertical process support 23, and a vertical process bottom through hole 24 which is coaxial with the vertical process top through hole 25 is arranged at the lower part of the vertical process support 23; a vertical process eccentric notch 26 is communicated with the side part of the vertical process top through hole 25 and the vertical process bottom through hole 24;

a module transmission data wire 28 of a computer component with the lower end and the module placing inner cavity 16 is hermetically arranged on the computer sealed outer heat exchange shell 14; a data line joint 29 exposed out of the water surface is arranged at the upper end of the module transmission data line 28, and a joint process seat 30 is arranged on one side of the data line joint 29;

a herringbone opening 31 of the joint is arranged on the cross arm of the joint craft seat 30;

a hub 33 is provided above the water surface to electrically plug the data line connector 29;

a moving manipulator 34 is arranged above the water surface, a first lifting outer top sleeve 35 is vertically lifted at the moving end of the moving manipulator 34, a second lifting inner rotating lifting rod 36 is arranged in the first lifting outer top sleeve 35 in a lifting mode, a lower supporting lifting arm 37 is arranged at the lower end of the second lifting inner rotating lifting rod 36,

after the lower lifting arm 37 sinks through the herringbone opening 31 of the joint, the lower lifting arm rotates to be in pressure contact with the lower surface of the joint process base 30, and the first lifting outer top sleeve 35 is in pressure contact with the upper surface of the joint process base 30;

a third lift line 38 and a fourth L-shaped replacement arm 40 are provided at the lower end of the transfer robot 34;

a third L-shaped lifting arm 39 is connected to the lower end of the third lifting line 38;

the fourth L-shaped replacing arm 40 enters along the front L-shaped groove 20 and moves transversely and then rises, and the hook head of the fourth L-shaped replacing arm 40 is positioned in the front technical space 21 so as to hook the sealed outer heat exchange shell 14 of the computer to be replaced;

the third L-shaped lifting arm 39 descends from the vertical process eccentric notch 26 of the topmost computer sealed outer heat exchange housing 14 to the next higher layer of computer sealed outer heat exchange housing 14 to be replaced and rotationally hooks the computer sealed outer heat exchange housing 14.

A protective wire jacket portion 32 is sealingly disposed on the computer sealed outer heat exchange housing 14, and the module transfer data lines 28 sealingly pass through the protective wire jacket portion 32.

The computer big data processing acquisition equipment comprises a computer storage grid component 2 with an L-shaped baffle frame 8 with an inclined plane; computer processing systems are stacked and stacked in the L-shaped baffle frame 8 with the inclined surface;

the L-shaped baffle frame 8 with the inclined plane is provided with a bottom inclined plane 9 with the root part lower than the end part, a process longitudinal clearance guide rail 10 is arranged between vertical plates of the L-shaped baffle frame 8 with the inclined plane, and the vertical plate of the L-shaped baffle frame 8 with the inclined plane is used for being in contact positioning with the back side surface of a computer sealed outer heat exchange shell 14;

a lifting sliding rear push seat 11 is lifted at the process longitudinal gap guide rail 10, and a process auxiliary outer push rod 12 and a process auxiliary pull-back arm 13 which are horizontally telescopic and distributed at high and low positions on the lifting sliding rear push seat 11;

the process auxiliary outer push rod 12 is used for pushing out the rear side of the computer sealing outer heat exchange shell 14 to be replaced;

the process auxiliary pullback arm 13 is used to hook into the process groove at the rear side of the computer sealed outer heat exchange housing 14 at the lower layer to be replaced.

The computer big data processing acquisition system of the embodiment comprises a computer outer frame assembly 1 and acquisition equipment in water of the computer outer frame assembly 1;

the computer outer frame body assembly 1 comprises an outer sealing shell 3;

an inner seal housing 4 is arranged in the outer seal housing 3.

A circulating pipeline 5 communicated with the interlayer and a circulating pump 7 connected with the circulating pipeline 5 are respectively arranged on the outer sealed shell 3, and a thermometer 6 is arranged on the outer sealed shell 3;

the sandwich of the outer sealed housing 3 is filled with a cooling liquid.

According to the acquisition method for computer big data processing, big data acquisition, processing calculation, storage and output are sequentially executed through a computer component; when a computer component needs to be replaced, the following steps are performed,

s1, the third L-shaped lifting arm 39 descends from the vertical process eccentric notch 26 of the topmost computer sealed outer heat exchange shell 14 to the computer sealed outer heat exchange shell 14 of the previous layer to be replaced and rotates to hook the computer sealed outer heat exchange shell 14 to lift, so that the bottom sliding seat 19 is separated from the top guide rail 18;

s2, pushing out the rear side of the computer sealed outer heat exchange shell 14 to be replaced by the process auxiliary outer push rod 12, and hooking the process auxiliary pullback arm 13 in the process groove at the rear side of the computer sealed outer heat exchange shell 14 at the lower layer to be replaced;

s3, the fourth L-shaped replacing arm 40 moves along the front L-shaped groove 20 to enter and transversely move and then ascends, the hook head of the fourth L-shaped replacing arm 40 is positioned in the front process space 21 to hook the computer sealed outer heat exchange shell 14 to be replaced, and the bottom sliding seat 19 slides along the top guide rail 18;

and S4, lowering the computer sealing outer heat exchange shell 14 of the previous layer to be replaced by one layer.

Although the invention is directed to a system for collecting a computer, the invention can also be used for cooling other large-data computer units, cooling liquid is stored in the outer frame body assembly 1 of the computer, a computer storage grid assembly 2 is used as a placing carrier, the outer sealing shell 3 and the inner sealing shell 4 realize multi-layer cooling, a circulating pipeline 5, a thermometer 6 and a circulating pump 7 realize auxiliary circulation to ensure the temperature of the liquid to be consistent, an L-shaped baffle frame 8 with an inclined plane is used as the carrier, the assembly can be conveniently replaced through no shielding at the front end, the inclined plane 9 at the bottom realizes positioning to avoid side collapse, a process longitudinal clearance guide rail 10, a lifting sliding rear push seat 11, a process auxiliary outer push rod 12 and a process auxiliary pull-back arm 13 realize rear push-out to avoid carrying and dislocation of the lower assembly, the outer heat exchange shell 14 of the computer can be metal, the inner cavity 15 is vertically isolated, the inner cavity 16 is placed in a module, the space 21 in the front process is reasonably distributed, the operation is convenient, the water-blocking breathable breathing net film 17 ensures pressure balance, preferably, the top guide rail 18, the bottom sliding seat 19 realize guiding, the front L-shaped groove 20, the shell sealing cover 22, the vertical process support 23, the vertical process bottom through hole 24, the vertical process top through hole 25, the vertical process eccentric notch 26, the vertical lifting inner cavity 27, the module transmission data line 28, the data line connector 29, the connector process seat 30 and the connector herringbone opening 31, so that the plugging and unplugging of the interface are realized, the replacement is convenient, the design is ingenious, the realization of automation is ensured, the unmanned operation is realized, and the confidentiality is good. The outer sleeve part 32 of protection line plays the protection, and the concentrator 33 makes things convenient for data connection, and the removal manipulator 34 is general, can be a plurality of, and first lift outer top cover 35, second lift internal rotation lifter 36 hold in the palm down and lift arm 37, third lifting wire 38, third L type hold in the palm and lift arm 39, thereby the fourth L type is changed arm 40 and is cooperated the completion and correspond the effect.

Claims (6)

1. A computer processing system, characterized by: comprises a computer sealed outer heat exchange shell;

a vertical isolation inner cavity (15), a front process inner space (21) and a module placing inner cavity (16) for placing a computer component are arranged in the inner cavity of the heat exchange shell outside the computer seal;

the vertical isolation inner cavity (15) and the front technical inner space (21) are positioned at the rear and front sides of the module placing inner cavity (16); a shell sealing cover (22) is arranged on the top wall of the module placing inner cavity (16);

a water-blocking breathable net film (17) is arranged on the heat exchange shell outside the computer seal, and the aperture of the water-blocking breathable net film (17) is smaller than the diameter of water molecules;

a bottom sliding seat (19) is arranged at the bottom of the computer sealed outer heat exchange shell, and a top guide rail (18) is arranged at the top of the computer sealed outer heat exchange shell;

when the computer sealed outer heat exchange shell is laminated, the bottom sliding seat (19) of the upper layer of computer sealed outer heat exchange shell slides on the top guide rail (18) of the lower layer of computer sealed outer heat exchange shell;

a front L-shaped channel (20) with an opening at the upper end is arranged on the front side surface of the space (21) in the front process, a vertical process support (23) is arranged in the vertical isolation inner cavity (15), a vertical lifting inner cavity (27) is arranged in the vertical process support (23) in a hollow manner, a vertical process top through hole (25) is arranged at the upper part of the vertical process support (23), and a vertical process bottom through hole (24) which is coaxial with the vertical process top through hole (25) is arranged at the lower part of the vertical process support (23); a vertical process eccentric opening (26) is communicated with the side part of the vertical process top through hole (25) and the vertical process bottom through hole (24);

a module transmission data line (28) of a computer component with the lower end and a module placing inner cavity (16) is hermetically arranged on the computer sealed outer heat exchange shell; a data line joint (29) exposed out of the water surface is arranged at the upper end of the module transmission data line (28), and a joint process seat (30) is arranged on one side of the data line joint (29);

a herringbone opening (31) of the joint is arranged on the cross arm of the joint craft seat (30);

a mobile manipulator (34) is arranged above the water surface, a first lifting outer top sleeve (35) is vertically lifted at the moving end of the mobile manipulator (34), a second lifting inner rotating lifting rod (36) is arranged in the first lifting outer top sleeve (35) in a lifting way, a lower lifting arm (37) is arranged at the lower end of the second lifting inner rotating lifting rod (36),

after the lower lifting arm (37) sinks to pass through the herringbone opening (31) of the joint, the lower lifting arm rotates to be in pressure contact with the lower surface of the joint process seat (30), and the first lifting outer jacking sleeve (35) is in pressure contact with the upper surface of the joint process seat (30);

a third lifting line (38) and a fourth L-shaped replacement arm (40) are respectively arranged at the lower end of the mobile manipulator (34);

a third L-shaped lifting arm (39) is connected to the lower end of the third lifting line (38);

a fourth L-shaped replacing arm (40) moves along the front L-shaped groove (20) to enter and transversely move and then ascend, and a hook head of the fourth L-shaped replacing arm (40) is positioned in the front process space (21) to hook the computer sealing outer heat exchange shell to be replaced;

the third L-shaped lifting arm (39) descends from the vertical process eccentric notch (26) of the topmost computer sealed outer heat exchange shell to the upper layer of the computer sealed outer heat exchange shell to be replaced and rotationally hooks the computer sealed outer heat exchange shell.

2. The computer processing system of claim 1, wherein: a protective wire jacket part (32) is hermetically arranged on the heat exchange shell outside the computer seal, and a module transmission data wire (28) hermetically penetrates through the protective wire jacket part (32);

a hub (33) is arranged above the water surface for electrical connection with the data line connector (29).

3. The utility model provides a collection equipment of computer big data processing which characterized in that: comprising a computer storage grid assembly (2) having an L-shaped shelf (8) with a ramp; stacking the computer processing system of claim 1 in an L-shaped shelf (8) with a slope;

the L-shaped baffle frame (8) with the inclined plane is provided with a bottom inclined plane (9) with the root part lower than the end part, a process longitudinal clearance guide rail (10) is arranged between vertical plates of the L-shaped baffle frame (8) with the inclined plane, and the vertical plate of the L-shaped baffle frame (8) with the inclined plane is used for being in contact with and positioning the rear side surface of the heat exchange shell outside the computer seal;

a lifting sliding back push seat (11) is lifted at the position of the process longitudinal gap guide rail (10), and a process auxiliary outer push rod (12) and a process auxiliary pull-back arm (13) which are horizontally telescopic and distributed at high and low positions on the lifting sliding back push seat (11);

the process auxiliary outer push rod (12) is used for pushing out the rear side of the computer sealed outer heat exchange shell to be replaced;

the process auxiliary pull-back arm (13) is used for hooking the process groove on the rear side of the computer sealing outer heat exchange shell of the lower layer to be replaced.

4. A computer big data processing's collection system which characterized in that: it comprises a computer outer frame assembly (1) and the acquisition equipment of claim 3 in the water of the computer outer frame assembly (1);

the computer outer frame body assembly (1) comprises an outer sealing shell (3);

an inner sealing housing (4) is arranged in the outer sealing housing (3).

5. The computer big data processing acquisition system according to claim 4, wherein: a circulating pipeline (5) communicated with the interlayer and a circulating pump (7) connected with the circulating pipeline (5) are respectively arranged on the outer sealed shell (3), and a thermometer (6) is arranged on the outer sealed shell (3);

the interlayer of the outer sealed shell (3) is filled with cooling liquid.

6. A computer big data processing acquisition method is characterized by comprising the following steps: big data acquisition, processing calculation, storage and output are sequentially executed through a computer component; when a computer component needs to be replaced, the following steps are performed,

s1, descending a third L-shaped lifting arm (39) from a vertical process eccentric notch (26) of the topmost computer sealed outer heat exchange shell to the upper layer of the computer sealed outer heat exchange shell to be replaced and rotating to hook the computer sealed outer heat exchange shell to lift, so that the bottom sliding seat (19) is separated from the top guide rail (18);

s2, pushing out the rear side of the computer sealed outer heat exchange shell to be replaced by the process auxiliary outer push rod (12), and hooking the process auxiliary pull-back arm (13) in the process groove at the rear side of the computer sealed outer heat exchange shell at the lower layer to be replaced;

s3, the fourth L-shaped replacing arm (40) moves to enter along the front L-shaped groove (20) and moves transversely to ascend, the hook head of the fourth L-shaped replacing arm (40) is positioned in the front process inner space (21) to hook the sealed outer heat exchange shell of the computer to be replaced, and the bottom sliding seat (19) slides along the top guide rail (18);

and S4, lowering the computer sealing outer heat exchange shell of the previous layer to one layer.

Images