CN117693168A

CN117693168A - Waste heat power generation system of data center

Info

Publication number: CN117693168A
Application number: CN202311737003.9A
Authority: CN
Inventors: 李楠
Original assignee: Nantong Heyun Energy Saving Equipment Co ltd
Current assignee: Nantong Heyun Energy Saving Equipment Co ltd
Priority date: 2023-12-18
Filing date: 2023-12-18
Publication date: 2024-03-12
Anticipated expiration: 2043-12-18
Also published as: CN118555800A; CN117693168B

Abstract

The invention discloses a data center waste heat power generation system, which relates to the technical field of waste heat power generation and comprises a machine plate, a heat pump, a heat radiating device and an error touch preventing device, wherein the heat radiating device comprises a heat radiating air pipe, a heat radiating rod, heat radiating blades, a matching rod, a sliding frame, a filter plate, a cleaning rod and a hollow ring, the cleaning rod moves upwards to scratch and clean the surface of the filter plate, the heat radiating air pipe is fixedly arranged on the surface of the machine plate, the surface of the heat radiating air pipe is provided with a heat radiating motor, the heat radiating rod is fixedly arranged at the output end of the heat radiating motor, the heat radiating blades are fixedly arranged on the surface of the heat radiating rod, the filter plate can filter dirt to prevent the dirt from being fed into the heat pump to cause pollution, the surface of the filter plate is cleaned to help to improve the heat exchange efficiency of a heat radiating pipeline, the dirt deposited on the filter plate can slow down the conduction of heat, the recovery efficiency of waste heat is influenced, and the cleaning can restore the normal working state of the heat radiating system.

Description

Waste heat power generation system of data center

Technical Field

The invention relates to the technical field of waste heat power generation, in particular to a data center waste heat power generation system.

Background

The data center waste heat power generation system is generally used for recovering and utilizing waste heat energy generated by a data center, thereby achieving the effects of improving energy efficiency and reducing environmental impact.

Patent publication number CN209068588U relates to a data center waste heat recovery system comprising: the evaporator, the first heat exchanger, the second heat exchanger and the heat supply terminal; the first heat exchanger and the second heat exchanger respectively comprise an inner pipe channel and an annular channel sleeved outside the inner pipe channel, and a fan is arranged outside the annular channel; the evaporator is arranged in the machine room, the evaporator is communicated with the annular channel of the first heat exchanger to form a loop, the inner tube channel of the first heat exchanger is communicated with the annular channel of the second heat exchanger to form a loop, and the inner tube channel of the second heat exchanger is communicated with the heat supply tail end to form a loop. According to the waste heat recovery system of the data center, the fans are arranged in the first heat exchanger and the second heat exchanger, when the recovered waste heat is larger than the heating amount required by the surrounding buildings, the redundant waste heat can be discharged to the environment by starting the fans, devices such as a cooling tower can be avoided, the occupied area of equipment is reduced, and the initial investment of the system is saved.

In the above patent, by disposing fans in the first heat exchanger and the second heat exchanger, devices such as a cooling tower can be avoided, but a heat dissipating device is not disposed at the heat source, waste heat generated at the heat source generally causes high temperature, if the heat dissipating device is not proper, the waste heat may not be effectively dissipated, so that the temperature is too high, heat damage is generated to equipment and pipelines, meanwhile, the waste heat cannot be recovered at the heat source to the maximum extent, the waste heat is wasted, and the proper heat dissipating device can help to effectively recover and utilize the waste heat, convert the waste heat into useful heat energy, and reduce energy consumption.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides a data center waste heat power generation system, which solves the problems in the background art.

In order to achieve the above purpose, the invention is realized by the following technical scheme: the utility model provides a data center waste heat power generation system, includes board and heat pump, still includes heat abstractor and mistake touch device, and wherein, heat abstractor includes heat dissipation tuber pipe, heat dissipation pole, heat dissipation leaf, cooperation pole, sliding frame, filter, clean pole and hollow circle, and clean pole upwards moves and scrapes the clearance to the filter surface, heat dissipation tuber pipe fixed mounting is on board surface, heat dissipation tuber pipe surface is provided with the heat dissipation motor, heat dissipation pole fixed mounting is at the heat dissipation motor output, heat dissipation leaf fixed mounting is on heat dissipation pole surface, cooperation pole hinge mounting is on heat dissipation pole surface, sliding frame slidable mounting is on heat dissipation pole surface, the louvre has been seted up on heat dissipation tuber pipe surface, the filter hinge mounting is at the louvre inner wall, clean pole slidable mounting is on the filter surface, hollow circle hinge mounting is on clean pole surface, and the filter can filter dirt and prevent that dirt from being sent into the inside heat pump and polluting that the clearance filter surface helps improving the heat exchange efficiency of heat dissipation pipe, and the dirt on the filter can slow down the heat recovery efficiency of influence, and the clearance can resume the normal operating condition of heat dissipation system.

According to the technical scheme, cooperation pole fixed surface installs the balancing weight, be provided with a spring between sliding frame and the radiating rod, sliding frame fixed surface installs the contact block, be provided with No. two springs between clean pole and the hollow circle, be provided with No. three springs between filter and the radiating wind pipe, sliding frame and hollow circle contact, clean pole removes and makes two filter remove the louvre with the back to back mutually to two filter, through removing the filter, can control the opening and shutting of louvre, helps optimizing the radiating wind channel, improves radiating efficiency, and radiating efficiency can improve can make waste heat recovery efficiency improve in step.

According to the technical scheme, prevent mistake touch device is including placing frame, control lever and flexible piece, and manual rotation control lever is rotatory, and the free end of the rotatory extrusion flexible piece of control lever is retracted, the heat pump surface is provided with tuber pipe A, place frame fixed mounting at tuber pipe A surface, place the frame surface and seted up the removal hole, remove hole surface slidable mounting and have the slider, control lever slidable mounting is on the slider surface, flexible piece fixed mounting is placing the frame top, the control groove has been seted up on the control lever surface, flexible piece free end and control groove contact, prevent mistake touch device can ensure that the pipeline keeps fixed when the operation, reduces the risk that probably leads to the pipeline to drop or become flexible, and the pipeline becomes flexible can cause the unnecessary leakage of waste heat, reduces waste heat recovery's efficiency.

According to the technical scheme, place frame top fixed mounting and have the fixed block, the fixed block top rotates and installs the bull stick, fixed block top fixed mounting has the restriction pole, flexible piece free end is provided with the rubber piece, the inside non-Newtonian fluid that is provided with of rubber piece, be provided with No. four springs between bull stick and the fixed block, be provided with scroll spring between slider and the placing frame, non-Newtonian fluid can solidify in the twinkling of an eye when receiving quick extrusion, leads to non-Newtonian fluid to only carrying out slow promotion and makes it flow, gives sufficient time and probably seems to prolong the time of whole maintenance process, but in fact, through reducing error and accident, can improve holistic work efficiency.

According to the technical scheme, still include leak protection device and buffer, leak protection device includes connecting frame, connecting block, tuber pipe B and stopper, treat that connecting block and spacing in spacing hole remove back tuber pipe A to the direction of keeping away from the heat pump for tuber pipe A breaks away from the connection with the heat pump, connecting frame fixed mounting is on the heat pump surface, the spread groove has been seted up on the connecting frame surface, connecting block slidable mounting is at the spread groove inner wall, tuber pipe B slidable mounting is on tuber pipe A surface, spacing hole has been seted up on tuber pipe A surface, stopper slidable mounting is at spacing hole inner wall, and maintenance time can be saved greatly not dismantling whole pipeline, through local maintenance, can solve the problem more rapidly, reduces system downtime.

According to the technical scheme, the seal groove has been seted up to tuber pipe A inner wall, seal groove inner wall fixed mounting has the gasbag, be provided with No. five springs between connecting frame and the connecting block, be provided with No. six springs between tuber pipe A and the stopper, the connecting block contacts with the stopper, stopper and control lever contact, the one end that heat pump was kept away from to tuber pipe B is connected with the board, has improved the leakproofness of pipeline between tuber pipe A and the heat pump, and efficient leakproofness can prevent the loss of waste heat, keeps the good leakproofness of pipeline to help guaranteeing energy transmission's efficiency, promotes the efficiency of waste heat recovery electricity generation.

According to the technical scheme, buffer includes buffer frame, buffer board, protection shield, connecting rod and buffer spring, prevents that tuber pipe A from removing the damage between the too fast pipeline that causes, buffer frame fixed mounting is at tuber pipe B inner wall, buffer board slidable mounting is at buffer frame inner wall, the protection shield articulates the installation at buffer board surface, connecting rod fixed mounting is at buffer board surface, be provided with buffer spring between buffer board and the buffer frame, buffer hole has been seted up on the buffer board surface, prevents that tuber pipe A from removing the damage between the fast pipeline that causes, helps reducing unexpected risk under the unexpected condition, and the while slow movement can react for more time of operating personnel to improve operational environment's security.

According to the technical scheme, the protection hole has been seted up to the protection shield surface, the one end that the buffer board was kept away from to the connecting rod and tuber pipe A fixed connection, be provided with No. seven springs between buffer board and the protection shield, can drive the protection shield through No. seven springs and reset.

The invention provides a data center waste heat power generation system. The beneficial effects are as follows:

(1) This data center waste heat power generation system, hollow circle removes and extrudes clean pole and upwards moves and scratch the clearance to the filter surface, the filter can filter the dirt and prevent that the dirt from being sent into the heat pump inside and cause the pollution, the clearance filter surface helps improving the heat exchange efficiency of heat dissipation pipeline, the dirt of deposit on the filter can slow down the conduction of heat, influence the recovery efficiency of waste heat, and the clearance can resume cooling system's normal operating condition, wait to clean pole and deflect to the unable time of continuing of biggest angle simultaneously, can make two filter move mutually in opposite directions and spill the louvre, through removing the filter, can control opening and shutting of louvre, help optimizing the heat dissipation wind channel, improve the radiating efficiency, the radiating efficiency can improve and can make waste heat recovery efficiency improve in step.

(2) This data center waste heat power generation system need disassemble mistake proofing device earlier when dismantling tuber pipe A for mistake proofing device can ensure that the pipeline remains fixed when the operation, reduces the risk that probably leads to the pipeline to drop or become flexible, and the pipeline becomes flexible can cause the unnecessary leakage of waste heat, reduces waste heat recovery's efficiency, is difficult to quick natural recovery after the spacing of telescopic block and control lever is relieved simultaneously, has given the abundant time of dismantlement personnel and has relieved other restriction keys, gives sufficient time and probably seems to prolong the time of whole maintenance process, but in fact, through reducing mistake and accident, can improve holistic work efficiency.

(3) This data center waste heat power generation system, after the spacing of connecting block and spacing hole is relieved, tuber pipe A can break away from automatically and be connected with the heat pump, need not dismantle whole pipeline can overhaul the heat pump, can save maintenance time greatly not dismantle whole pipeline, through local maintenance, can solve the problem more rapidly, reduce system downtime, simultaneously when dock tuber pipe A43 and heat pump, the gasbag receives tuber pipe A's extrusion back and produces deformation and pack the gap between tuber pipe A and the linking frame, the leakproofness of pipeline between tuber pipe A and the heat pump has been improved, the loss of waste heat can be prevented to efficient leakproofness, keep the good leakproofness of pipeline to help guaranteeing energy transmission's efficiency, promote waste heat recovery power generation's efficiency.

(4) This data center cogeneration system can only the slow movement through the buffer board make connecting rod and tuber pipe A only can the slow movement, when dismantling the pipeline, prevent that tuber pipe A from moving too fast and causing the damage between the pipeline, help reducing unexpected risk under the emergency, simultaneously the slow movement can react for more time of operating personnel to improve operational environment's security.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present invention;

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

FIG. 3 is a schematic diagram of the positions of the heat dissipation bars and heat dissipation blades according to the present invention;

FIG. 4 is an enlarged schematic view of the portion A of FIG. 3 according to the present invention;

FIG. 5 is an enlarged schematic view of the portion B of FIG. 2 according to the present invention;

FIG. 6 is a schematic view of the position structure of the connecting frame and the connecting block according to the present invention;

FIG. 7 is a schematic view showing the position structures of the air duct A and the air bag according to the present invention;

FIG. 8 is an enlarged schematic view of the portion C of FIG. 7 according to the present invention;

FIG. 9 is an enlarged schematic view of the portion D of FIG. 7 according to the present invention;

FIG. 10 is a schematic view of the position structure of the buffer frame and the buffer plate according to the present invention.

In the figure: 1. a body; 21. a heat dissipation air pipe; 22. a heat dissipation rod; 23. radiating leaves; 24. a mating lever; 25. a sliding frame; 26. a filter plate; 27. a cleaning lever; 28. a hollow ring; 31. placing a frame; 32. a control lever; 33. a telescopic block; 34. a rubber block; 35. a fixed block; 36. a rotating rod; 37. a restraining bar; 41. a connection frame; 42. a connecting block; 43. an air pipe A; 44. an air pipe B; 45. an air bag; 46. a limiting block; 51. a buffer frame; 52. a buffer plate; 53. a protective plate; 54. a connecting rod; 55. a buffer spring; 6. and (3) a heat pump.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-8, one embodiment of the present invention is: the utility model provides a data center waste heat power generation system, including board 1 and heat pump 6, still include heat abstractor and mistake touch device, wherein, heat abstractor includes the heat dissipation tuber pipe 21, the radiating rod 22, the radiating leaf 23, the cooperation pole 24, the sliding frame 25, the filter 26, clean pole 27 and hollow circle 28, the contact piece moves to the direction of keeping away from the radiating leaf 23 and drives the sliding frame 25 and remove, sliding frame 25 moves and hollow circle 28 contact extrusion hollow circle 28 and remove, hollow circle 28 removes extrusion clean pole 27 and upwards move, clean pole 27 upwards moves and scratch the clearance to filter 26 surface, heat dissipation tuber pipe 21 fixed mounting is at board 1 surface, the radiating tuber pipe 21 surface is provided with the heat dissipation motor, radiating pole 22 fixed mounting is at the heat dissipation motor output, radiating leaf 23 fixed mounting is at the radiating pole 22 surface, the cooperation pole 24 is articulated to be installed at the radiating pole 22 surface, sliding frame 25 slidable mounting is at the radiating rod 22 surface, the radiating hole is seted up on the radiating tuber pipe 21 surface, the filter 26 is articulated to be installed at the radiating hole inner wall, clean pole 27 slidable mounting is at the 26 surface, hollow circle 28 articulatedly installs at clean pole 27 surface, the filter 26 can prevent that the filter 26 from being carried forward by filter 6 to the inside the heat pump of filter pipe and the heat pump 26 from leading to the heat exchange to the normal work of heat recovery state of heat dissipation system of heat dissipation effect can be improved.

The balancing weight is fixedly arranged on the surface of the matching rod 24, a first spring is arranged between the sliding frame 25 and the radiating rod 22, a contact block is fixedly arranged on the surface of the sliding frame 25, a second spring is arranged between the cleaning rod 27 and the hollow ring 28, a third spring is arranged between the filter plate 26 and the radiating air pipe 21, the sliding frame 25 is in contact with the hollow ring 28, the cleaning rod 27 moves to extrude the two filter plates 26, so that the two filter plates 26 move away from each other to leak out the radiating hole, the opening and closing of the radiating hole can be controlled through moving the filter plates 26, the radiating air duct is helped to be optimized, the radiating efficiency is improved, and the waste heat recovery efficiency is synchronously improved.

The anti-misoperation device comprises a placing frame 31, a control rod 32 and a telescopic block 33, when the heat pump 6 is overhauled, the heat pump 6 and an air pipe A43 are detached firstly, the control rod 32 is rotated manually, the control rod 32 is rotated to extrude the free end of the telescopic block 33 to retract, the air pipe A43 is arranged on the surface of the heat pump 6, the placing frame 31 is fixedly arranged on the surface of the air pipe A43, a moving hole is formed in the surface of the placing frame 31, a sliding block is slidably arranged on the surface of the moving hole, the control rod 32 is slidably arranged on the surface of the sliding block, the telescopic block 33 is fixedly arranged at the top of the placing frame 31, a control groove is formed in the surface of the control rod 32, the free end of the telescopic block 33 is in contact with the control groove, the anti-misoperation device can ensure that a pipeline is kept fixed during operation, the risk that the pipeline is possibly dropped or loosened is reduced, the pipeline is loosened to cause unnecessary leakage of waste heat, and the waste heat recovery efficiency is reduced.

The fixed block 35 is fixedly arranged at the top of the placement frame 31, the rotating rod 36 is rotatably arranged at the top of the fixed block 35, the limiting rod 37 is fixedly arranged at the top of the fixed block 35, the rubber block 34 is arranged at the free end of the telescopic block 33, non-Newtonian fluid is arranged in the rubber block 34, a fourth spring is arranged between the rotating rod 36 and the fixed block 35, a vortex spring is arranged between the sliding block and the placement frame 31, the free end of the telescopic block 33 is limited by the non-Newtonian fluid in the rubber block 34 to move slowly, the non-Newtonian fluid is instantly solidified when being rapidly extruded, the non-Newtonian fluid can be pushed slowly to flow, enough time is given to prolong the time of the whole maintenance process, and the whole working efficiency can be improved by reducing errors and accidents.

When the machine body of the data center works, when the running speed of the machine body of the data center is high, the machine body can conduct larger-power heat dissipation through the rotating speed of the heat dissipation blades 23 and the heat dissipation rods 22, the heat dissipation rods 22 rotate at a high speed to drive the matching rods 24 to rotate quickly, the matching rods 24 rotate quickly to drive the balancing weights to rotate quickly, the matching rods 24 and the balancing weights rotate quickly under the action of centrifugal force, the matching rods 24 deflect with the balancing weights, the contact blocks contact and squeeze the contact blocks to move in the direction away from the heat dissipation blades 23, the contact blocks move in the direction away from the heat dissipation blades 23 to drive the sliding frame 25 to move, the sliding frame 25 moves to move with the hollow rings 28 to contact and squeeze the hollow rings 28, the hollow rings 28 move to squeeze the cleaning rods 27 to move upwards, the cleaning rods 27 move upwards to scratch and clean the surfaces of the filtering plates 26, and when the cleaning rods 27 deflect to the maximum angle can not continue to deflect, the sliding frame 25 moves away from the hollow rings 28 and the cleaning rods 27 to squeeze the two filtering plates 26, the two filtering plates 26 move back to the direction to the contact blocks, and the heat dissipation holes 21, and the heat dissipation effect of the heat dissipation air pipes 21 is further improved.

When the heat pump 6 needs to be overhauled, the heat pump 6 and the air pipe A43 are detached firstly, the control rod 32 is manually rotated, the control rod 32 is rotationally extruded to retract the free end of the telescopic block 33, the free end of the telescopic block 33 is driven to move towards the direction far away from the heat pump 6 when retracting, the rubber block 34 is driven to move towards the direction far away from the heat pump 6 to extrude the rotary rod 36 to rotate anticlockwise, the limit of the limiting rod 37 is not met when the rotary rod 36 rotates anticlockwise, when the control rod 32 is manually loosened, the control rod 32 is reset under the elastic force of the vortex spring, the control rod 32 is reset to enable the free end of the telescopic block 33 to move towards the direction close to the heat pump 6, the free end of the telescopic block 33 is driven to move towards the direction close to the heat pump 6 to drive the rubber block 34, the rubber block 34 is driven to move to rotate clockwise by the contact with the rotary rod 36, the limit rod 36 is limited by the limiting rod 37 when rotating clockwise, the free end of the telescopic block 36 is limited to move towards the rubber block 34, the limit is limited by the non-Newton fluid inside the telescopic block 34, the free end of the telescopic block 33 can only slowly move towards the limit of the free end of the telescopic block 33, and the limit of the telescopic block 33 can not be fully removed by other people, and the limit of the quick-dismantling time is difficult to be relieved.

Referring to fig. 1-10, in another embodiment of the present invention, the present invention further includes a leakage preventing device and a buffering device, where the leakage preventing device includes a connection frame 41, a connection block 42, an air duct B44, and a limiting block 46, the connection block 42 moves downward to release the contact between the connection block 42 and the limiting hole and release the limit of the limiting hole, and after the release of the limit between the connection block 42 and the limiting hole, the air duct a43 moves in a direction away from the heat pump 6, so that the air duct a43 is released from the connection with the heat pump 6, the connection frame 41 is fixedly installed on the surface of the heat pump 6, a connection groove is formed on the surface of the connection frame 41, the connection block 42 is slidably installed on the inner wall of the connection groove, the air duct B44 is slidably installed on the surface of the air duct a43, the limiting hole is formed on the surface of the air duct a43, and the limiting block 46 is slidably installed on the inner wall of the limiting hole, so that maintenance time can be greatly saved without disassembling the whole pipeline, and the problem can be solved more rapidly by partial maintenance, and the system downtime can be reduced.

A sealing groove is formed in the inner wall of the air pipe A43, an air bag 45 is fixedly arranged on the inner wall of the sealing groove, a five-number spring is arranged between the connecting frame 41 and the connecting block 42, a six-number spring is arranged between the air pipe A43 and the limiting block 46, the connecting block 42 is in contact with the limiting block 46, the limiting block 46 is in contact with the control rod 32, one end, far away from the heat pump 6, of the air pipe B44 is connected with the machine board 1, the air bag 45 deforms to fill gaps between the air pipe A43 and the connecting frame 41, the sealing performance of a pipeline between the air pipe A43 and the heat pump 6 is improved, the efficient sealing performance can prevent waste heat loss, good sealing performance of the pipeline is kept to help ensure energy transmission efficiency, and waste heat recovery and power generation efficiency is improved.

The buffer device comprises a buffer frame 51, a buffer plate 52, a protection plate 53, a connecting rod 54 and a buffer spring 55, wherein the buffer plate 52 can only slowly move so that the connecting rod 54 can only slowly move, the connecting rod 54 can only slowly move so that an air pipe A43 can only slowly move, damage between pipelines caused by too fast movement of the air pipe A43 is prevented, the buffer frame 51 is fixedly arranged on the inner wall of an air pipe B44, the buffer plate 52 is slidably arranged on the inner wall of the buffer frame 51, the protection plate 53 is hinged to the surface of the buffer plate 52, the connecting rod 54 is fixedly arranged on the surface of the buffer plate 52, the buffer spring 55 is arranged between the buffer plate 52 and the buffer frame 51, buffer holes are formed in the surface of the buffer plate 52, damage between the pipelines caused by too fast movement of the air pipe A43 is prevented, unexpected risks in sudden situations are reduced, and meanwhile, the slow movement can react for more time of operators, so that the safety of a working environment is improved.

The protection hole has been seted up on protection board 53 surface, and the connecting rod 54 is kept away from the one end of buffer board 52 and tuber pipe A43 fixed connection, is provided with the spring of No. seven between buffer board 52 and the protection board 53, can drive protection board 53 through the spring of No. seven and reset.

When the embodiment works, after the limit of the free ends of the control rod 32 and the telescopic block 33 is released, the control rod 32 is manually pressed to move downwards, the control rod 32 moves downwards to contact with the limit block 46 to press the limit block 46 to move downwards, the limit block 46 moves downwards to press the connection block 42 to move downwards, the contact between the connection block 42 and the limit hole is released, the limit of the limit hole is released, the air duct A43 moves in the direction away from the heat pump 6 after the limit of the connection block 42 and the limit hole is released, so that the air duct A43 is separated from the heat pump 6, when the air duct A43 is in butt joint with the heat pump 6, the air duct A43 is manually aligned with the connection frame 41 to push the air duct A43 to move in the direction close to the heat pump 6, the movement of the air duct A43 drives the connection block 42 to move to be in the direction close to the heat pump 6 to limit the limit hole, meanwhile, the air duct A43 moves to press the air bag 45, deformation is generated after the air bag 45 is pressed by the air duct A43, the deformation is generated, the gap between the air duct A43 and the connection frame 41 is filled, and the tightness of a pipeline between the air duct A43 and the heat pump 6 is improved.

Manually pressing the control rod 32 downwards, the control rod 32 downwards moves to contact with the limiting block 46 to extrude the limiting block 46 downwards, the limiting block 46 downwards moves to extrude the connecting block 42 downwards, the connecting block 42 downwards moves to be separated from contact with the limiting hole to release the limit of the limiting hole, after the limit of the connecting block 42 and the limiting hole is released, the air pipe A43 moves in the direction away from the heat pump 6 under the action of the elasticity of the buffer spring 55, the air pipe A43 moves in the direction away from the heat pump 6 to drive the connecting rod 54 to move, the connecting rod 54 moves to drive the buffer plate 52 to move, the buffer plate 52 moves to drive the protection plate 53 to move, the protection plate 53 moves to be tightly attached to the surface of the buffer plate 52 under the action of negative pressure of gas inside the buffer frame 51, the protection plate 53 is tightly attached to the surface of the buffer plate 52 to enable the gas inside the buffer frame 51 to pass through the protection hole only slowly, the gas inside the buffer frame 51 passes through the protection hole only slowly, the buffer plate 52 can only move slowly, the connecting rod 54 can only move slowly, the air pipe A43 can only slowly move slowly, and damage between pipelines due to the fact that the air pipe A43 moves too quickly is prevented.

Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. A data center cogeneration system comprising a deck (1) and a heat pump (6), characterized by: the device also comprises a heat dissipation device, an error touch prevention device, a leakage prevention device and a buffer device;

wherein, heat abstractor includes heat dissipation tuber pipe (21), heat dissipation pole (22), heat dissipation leaf (23), cooperation pole (24), sliding frame (25), filter (26), clean pole (27) and hollow circle (28), heat dissipation tuber pipe (21) fixed mounting is in board (1) surface, heat dissipation tuber pipe (21) surface is provided with the heat dissipation motor, heat dissipation pole (22) fixed mounting is at the heat dissipation motor output, heat dissipation leaf (23) fixed mounting is on heat dissipation pole (22) surface, cooperation pole (24) hinged mounting is on heat dissipation pole (22) surface, sliding frame (25) slidable mounting is on heat dissipation pole (22) surface, the louvre has been seted up on heat dissipation tuber pipe (21) surface, filter (26) hinged mounting is at the louvre inner wall, clean pole (27) slidable mounting is on filter (26) surface, hollow circle (28) hinged mounting is on clean pole (27) surface.

2. A data center cogeneration system according to claim 1, wherein: the utility model discloses a cleaning device for the radiator, including cooperation pole (24) fixed surface installs the balancing weight, be provided with a spring between sliding frame (25) and radiator rod (22), sliding frame (25) fixed surface installs the contact block, be provided with No. two springs between clean pole (27) and hollow circle (28), be provided with No. three springs between filter (26) and radiator tube (21), sliding frame (25) and hollow circle (28) contact.

3. A data center cogeneration system according to claim 2, wherein: the anti-misoperation device comprises a placement frame (31), a control rod (32) and a telescopic block (33), wherein an air pipe A (43) is arranged on the surface of a heat pump (6), the placement frame (31) is fixedly installed on the surface of the air pipe A (43), a moving hole is formed in the surface of the placement frame (31), a sliding block is slidably installed on the surface of the moving hole, the control rod (32) is slidably installed on the surface of the sliding block, the telescopic block (33) is fixedly installed at the top of the placement frame (31), a control groove is formed in the surface of the control rod (32), and the free end of the telescopic block (33) is in contact with the control groove.

4. A data center cogeneration system according to claim 3, wherein: place frame (31) top fixed mounting has fixed block (35), fixed block (35) top rotation is installed bull stick (36), fixed block (35) top fixed mounting has restriction pole (37), flexible piece (33) free end is provided with rubber block (34), inside non-Newtonian fluid that is provided with of rubber block (34), be provided with No. four springs between bull stick (36) and fixed block (35), be provided with scroll spring between slider and the placement frame (31).

5. A data center cogeneration system according to claim 4, wherein: the anti-leakage device comprises a connecting frame (41), a connecting block (42), an air pipe B (44) and a limiting block (46), wherein the connecting frame (41) is fixedly installed on the surface of a heat pump (6), a connecting groove is formed in the surface of the connecting frame (41), the connecting block (42) is slidably installed on the inner wall of the connecting groove, the air pipe B (44) is slidably installed on the surface of an air pipe A (43), a limiting hole is formed in the surface of the air pipe A (43), and the limiting block (46) is slidably installed on the inner wall of the limiting hole.

6. A data center cogeneration system according to claim 5, wherein: seal groove has been seted up to tuber pipe A (43) inner wall, seal groove inner wall fixed mounting has gasbag (45), be provided with No. five springs between connecting frame (41) and connecting block (42), be provided with No. six springs between tuber pipe A (43) and stopper (46), connecting block (42) and stopper (46) contact, stopper (46) and control lever (32) contact, the one end that heat pump (6) was kept away from to tuber pipe B (44) is connected with board (1).

7. A data center cogeneration system according to claim 6, wherein: the buffering device comprises a buffering frame (51), a buffering plate (52), a protection plate (53), a connecting rod (54) and a buffering spring (55), wherein the buffering frame (51) is fixedly installed on the inner wall of an air pipe B (44), the buffering plate (52) is slidably installed on the inner wall of the buffering frame (51), the protection plate (53) is hinged to the surface of the buffering plate (52), the connecting rod (54) is fixedly installed on the surface of the buffering plate (52), the buffering spring (55) is arranged between the buffering plate (52) and the buffering frame (51), and buffering holes are formed in the surface of the buffering plate (52).

8. A data center cogeneration system according to claim 7, wherein: the protection hole is formed in the surface of the protection plate (53), one end, away from the buffer plate (52), of the connecting rod (54) is fixedly connected with the air pipe A (43), and a seventh spring is arranged between the buffer plate (52) and the protection plate (53).