CN116528569A - Indirect evaporative cooling heat dissipation system of data center - Google Patents

Abstract

The invention discloses an indirect evaporative cooling heat dissipation system of a data center, which relates to the technical field of heat dissipation equipment and comprises a base, wherein a heat dissipation fin is fixedly connected to the top surface of the base, an installation seat is attached to the middle end position of the top of the heat dissipation fin, screws are rotatably connected to the two sides of the installation seat, one ends of the screws are connected to the heat dissipation fin through threads, a fan is fixedly installed on the installation seat, a pair of heat conduction pipes are fixedly installed in the base, and one ends of the pair of heat conduction pipes are fixedly connected with copper pipes. The invention has reasonable structure, realizes the discharge of heat on the radiating fins through the operation of the fan, and installs the second heat conducting plate inside the server when the radiating work is carried out on a plurality of groups of processors, so that the second heat conducting plate is attached to the processors, and the first heat conducting plate moves on the second heat conducting plate through the operation of the servo motor, thereby being convenient for the radiating work of the plurality of groups of processors.

Description

Indirect evaporative cooling heat dissipation system of data center

Technical Field

The invention relates to the technical field of heat dissipation equipment, in particular to an indirect evaporative cooling heat dissipation system of a data center.

Background

The traditional data center generally adopts a refrigeration water circulation and mechanical refrigeration mode to dissipate heat in the data center, and the mode has large four-season power consumption and energy efficiency improvement and encounters a bottleneck; at present, natural cooling is adopted, namely direct fresh air cooling and indirect evaporative cooling are adopted, and the direct fresh air cooling can cause great pollution to a server for a long time due to dust impurities mixed with fresh air, so that the performance of the server is reduced, and the current mainstream indirect evaporative cooling equipment can not meet the annual cooling requirement of a data center, and mechanical refrigeration is still needed for assistance in summer; but in theory with the increasing maturity of indirect evaporative cooling technology applications.

The existing cooling and radiating equipment is characterized in that a heat conducting plate is attached to a processor of a server, heat generated by operation of the server is transferred to the heat conducting plate, radiating fins are arranged on the heat conducting plate, a fan is arranged on the radiating fins, the heat on the radiating fins is discharged through the fan, multiple groups of processors are arranged in the existing server, the multiple groups of processors are required to be cooled and radiated during installation, and the space in the server is easy to occupy.

Disclosure of Invention

An object of the application is to provide an indirect evaporative cooling system of data center, realized discharging the heat on the fin through the operation of fan, when carrying out the heat dissipation work to multiunit treater, install the second heat conduction board inside the server for the laminating of second heat conduction board is on the treater, makes first heat conduction board remove on the second heat conduction board through servo motor's operation, thereby is convenient for carry out the heat dissipation work to multiunit treater.

In order to achieve the above purpose, the present application provides the following technical solutions: the indirect evaporative cooling heat dissipation system of the data center comprises a base, wherein a heat dissipation fin is fixedly connected to the top surface of the base, an installation seat is attached to the middle end position of the top of the heat dissipation fin, screws are rotatably connected to the two sides of the installation seat, one end of each screw is in threaded connection with the heat dissipation fin, a fan is fixedly installed on the installation seat, a pair of heat conduction pipes are fixedly installed in the base, one end of each heat conduction pipe is fixedly connected with a copper pipe, the other end of each copper pipe is inserted into a connecting block, bolts are fixedly connected to the four corners of the base, first springs are sleeved on the bolts, the two ends of each first spring are respectively attached to one side of each bolt and the top surface of each connecting block, and the bottom ends of each bolt are in threaded connection with each first heat conduction plate; still include installation component, adjusting part and spacing subassembly, installation component is used for the cooperation the base uses, adjusting part is used for the cooperation first heat conduction board uses, spacing subassembly is used for the cooperation the base is whole uses.

Preferably, the installation component is including seting up the guide way of first heat-conducting plate bottom middle-end position, the inside laminating of guide way has the stopper, stopper fixed connection is on the second heat-conducting plate.

Preferably, the first through hole is formed in the limiting block, the second through hole is formed in the bottom end of the second heat conducting plate, and the first through hole and the second through hole are communicated with each other.

Preferably, the four corners of the second heat conducting plate are provided with assembly holes.

Preferably, the adjusting component comprises a pair of round holes formed in the first heat-conducting plate, a pair of sliding rods are movably inserted in the round holes, two ends of each sliding rod are fixedly connected with a butt joint seat, and the bottom ends of the butt joint seats are fixedly connected to the second heat-conducting plate.

Preferably, the first heat-conducting plate is provided with a threaded hole, the threaded hole is connected with a threaded rod in a threaded mode, one end of the threaded rod is sleeved with a limiting seat, the bottom end of the limiting seat is fixedly connected with the second heat-conducting plate, the other end of the threaded rod is rotatably connected with a supporting seat, and the bottom end of the supporting seat is fixedly connected with the second heat-conducting plate.

Preferably, one end of the threaded rod is fixedly connected with the output end of the servo motor, and the servo motor is fixedly installed on the second heat conducting plate.

Preferably, the limiting assembly comprises a limiting groove formed in the first heat-conducting plate, a limiting plate is arranged in the limiting groove, the bottom end of the limiting plate is fixedly connected to the second heat-conducting plate, and a plurality of groups of clamping grooves are formed in the top end surface of the limiting plate.

Preferably, the hinge seat is fixedly installed on the first heat-conducting plate, the hinge seat is rotationally connected with a rotating shaft, the rotating shaft is fixedly connected with the moving plate, the bottom end of the moving plate is fixedly connected with the inserting plate, and the bottom end of the inserting plate is inserted into one of the clamping grooves.

Preferably, the fixed block is fixedly connected to the first heat-conducting plate, the top plate is fixedly connected to the fixed block, the waist-shaped hole is formed in the top plate, the fixed column is inserted in the waist-shaped hole in a sliding mode, the diameter of the fixed column is smaller than the width of the waist-shaped hole, the bottom end of the fixed column is fixedly connected to the movable plate, the baffle is fixedly connected to the top end of the fixed column, the diameter of the baffle is larger than the width of the waist-shaped hole, the second spring is sleeved on the fixed column, and two ends of the second spring are respectively attached to the top end of the movable plate and the bottom end of the top plate.

In summary, the invention has the technical effects and advantages that:

1. the heat-conducting device is reasonable in structure, the four corners of the second heat-conducting plate are provided with the assembly holes, the second heat-conducting plate is fixedly arranged on the surfaces of a plurality of groups of processors, the bottom end of the second heat-conducting plate is attached to the processors, heat generated by the processors is conducted to the second heat-conducting plate, the second heat-conducting plate is fixedly provided with the limiting block, the limiting block is used for receiving the heat of the second heat-conducting plate, the second heat-conducting plate is attached to the first heat-conducting plate, the first heat-conducting plate slides on the limiting block through the guide groove on the first heat-conducting plate, the heat on the limiting block is conveniently conducted to the first heat-conducting plate, the base is attached to the first heat-conducting plate, the base absorbs the heat received by the first heat-conducting plate, the base is fixedly connected with the heat-conducting pipe, the base is used for conducting the heat into the heat-radiating fins through the copper pipe, and the heat on the heat-radiating fins is discharged through the operation of the fan;

2. according to the invention, when the guide groove on the first heat-conducting plate is required to slide on the limiting block, so that the first heat-conducting plate is convenient to conduct all heat on the limiting block, a round hole is formed in the first heat-conducting plate, a sliding rod is inserted into the round hole, the first heat-conducting plate is convenient to slide on the sliding rod when moving, the moving stability of the first heat-conducting plate is improved, a threaded hole is formed in the first heat-conducting plate, a threaded rod is connected with the internal threads of the threaded hole, one end of the threaded rod is fixedly connected with the output end of the servo motor, the threaded rod is rotated through the operation of the servo motor, so that the first heat-conducting plate can slide on the limiting block conveniently, and heat on the limiting block is conducted;

3. according to the invention, when the first heat conducting plate needs to be moved, the limiting groove is formed in the first heat conducting plate, the limiting plate is arranged in the limiting groove, the limiting plate is provided with the clamping groove through the movement of the first heat conducting plate, the first heat conducting plate is fixedly connected with the hinge seat, the hinge seat is rotationally connected with the rotating shaft, the rotating shaft is fixedly connected with the moving plate, the bottom end of the moving plate is fixedly connected with the plugboard, the bottom end of the plugboard which is elastic by the second spring is inserted into one of the two moving plates, when the first heat conducting plate needs to be moved, the moving plate is moved through pulling the baffle plate, and the plugboard is separated from the clamping groove through the movement of the moving plate, so that the whole first heat conducting plate is convenient to move, and the heat of the limiting blocks in different areas is conducted by the first heat conducting plate.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present application, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic perspective view of a base;

FIG. 2 is a schematic side perspective view of a base;

FIG. 3 is a schematic view of a bottom perspective of the base;

FIG. 4 is a schematic top perspective view of a base;

fig. 5 is a schematic bottom perspective view of the first heat conducting plate;

fig. 6 is a schematic side view of a first heat conducting plate;

FIG. 7 is a schematic top perspective view of a fan;

fig. 8 is an enlarged schematic view of fig. 2 at a.

In the figure: 1. a base; 102. a heat radiation fin; 103. a mounting base; 104. a screw; 105. a fan; 106. a heat conduction pipe; 107. copper pipe; 108. a connecting block; 109. a bolt; 110. a first spring; 112. a first heat-conducting plate; 2. a guide groove; 201. a limiting block; 202. a second heat-conducting plate; 203. a first through hole; 204. a second through hole; 205. a fitting hole; 3. a round hole; 301. a slide bar; 302. a butt joint seat; 303. a threaded hole; 304. a threaded rod; 305. a limit seat; 306. a support base; 307. a servo motor; 4. a limit groove; 401. a limiting plate; 402. a clamping groove; 403. a hinge base; 404. a rotating shaft; 405. a moving plate; 406. inserting plate; 407. a fixed block; 408. a top plate; 409. a waist-shaped hole; 410. fixing the column; 412. a baffle; 413. and a second spring.

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.

Examples: referring to the indirect evaporative cooling heat dissipation system of the data center shown in fig. 1-3, the indirect evaporative cooling heat dissipation system comprises a base 1, wherein a heat dissipation fin 102 is fixedly connected to the top end surface of the base 1, a mounting seat 103 is attached to the middle end position of the top of the heat dissipation fin 102, screws 104 are rotatably connected to two sides of the mounting seat 103, one end of each screw 104 is in threaded connection with the heat dissipation fin 102, a fan 105 is fixedly installed on the mounting seat 103, a pair of heat conduction pipes 106 are fixedly installed in the base 1, one ends of the pair of heat conduction pipes 106 are fixedly connected with copper pipes 107, the other ends of the copper pipes 107 are inserted into connecting blocks 108, bolts 109 are fixedly connected to four corners of the base 1, first springs 110 are sleeved on the bolts 109, two ends of each first spring 110 are respectively attached to one side of each bolt 109 and the top end surface of the connecting blocks 108, and the bottom ends of each bolt 109 are in threaded connection with a first heat conduction plate 112; still include installation component, adjusting part and spacing subassembly, installation component is used for cooperating base 1 to use, and adjusting part is used for cooperating first heat-conducting plate 112 to use, and spacing subassembly is used for cooperating base 1 to wholly use.

Specifically, it should be noted that, the fan 105 and the servo motor 307 are electrically connected to the external control unit through wires, the specific working principle is cited in the prior art, and not described in detail herein, the heat generated by the processor is transferred to the first heat conducting plate 112 through the limiting block 201 by attaching the second heat conducting plate 202 to the processor, then the guiding groove 2 is attached to the first heat conducting plate 112, the first heat conducting plate 112 transfers the received heat to the base 1, the heat conducting tube 106 is installed on the base 1, the heat on the base 1 is transferred to the heat dissipating fins 102 through the heat conducting tube 106, and then the heat on the heat dissipating fins 102 is conveniently discharged through the operation of the fan 105.

As an implementation manner in this embodiment, according to fig. 4 and 5, the mounting assembly includes a guide groove 2 formed at a middle end position of a bottom of the first heat-conducting plate 112, a limiting block 201 is attached to an inner portion of the guide groove 2, the limiting block 201 is fixedly connected to the second heat-conducting plate 202, a first through hole 203 is formed in the limiting block 201, a second through hole 204 is formed in a bottom end of the second heat-conducting plate 202, the first through hole 203 and the second through hole 204 are mutually communicated, and assembly holes 205 are formed at four corners of the second heat-conducting plate 202.

Specifically, the four corners of the second heat-conducting plate 202 are provided with assembly holes 205, the second heat-conducting plate 202 is fixedly installed on the surfaces of a plurality of groups of processors, so that the bottom end of the second heat-conducting plate 202 is attached to the processors, heat generated by the processors is conducted to the second heat-conducting plate 202, a limiting block 201 is fixedly installed on the second heat-conducting plate 202, heat of the second heat-conducting plate 202 is received through the limiting block 201, the first heat-conducting plate 112 is attached to the second heat-conducting plate 202, the limiting block 201 slides through a guide groove 2 on the first heat-conducting plate 112, the heat of the limiting block 201 is conveniently conducted to the first heat-conducting plate 112, a base 1 is attached to the first heat-conducting plate 112, the heat received by the first heat-conducting plate 112 is absorbed by the base 1, a heat-conducting pipe 106 is installed on the base 1, copper pipes 107 are fixedly connected to the heat-conducting pipes 106, the base 1 conducts the heat into the heat-radiating fins 102 through the copper pipes 107, and the heat of the heat on the heat-radiating fins 102 is discharged through the operation of the fans 105.

As an implementation manner in this embodiment, according to fig. 6 and 7, the adjusting assembly includes a pair of round holes 3 formed on the first heat-conducting plate 112, a slide rod 301 is movably inserted in the pair of round holes 3, two ends of the slide rod 301 are fixedly connected with a docking seat 302, a bottom end of the docking seat 302 is fixedly connected with the second heat-conducting plate 202, a threaded hole 303 is formed on the first heat-conducting plate 112, a threaded rod 304 is connected with the threaded hole 303 in a threaded manner, a limit seat 305 is sleeved at one end of the threaded rod 304, a bottom end of the limit seat 305 is fixedly connected with the second heat-conducting plate 202, the other end of the threaded rod 304 is rotatably connected with a supporting seat 306, a bottom end of the supporting seat 306 is fixedly connected with the second heat-conducting plate 202, one end of the threaded rod 304 is fixedly connected with an output end of a servo motor 307, and the servo motor 307 is fixedly mounted on the second heat-conducting plate 202.

Specifically, when the guide groove 2 on the first heat-conducting plate 112 is required to slide on the limiting block 201, the first heat-conducting plate 112 is convenient to conduct all heat on the limiting block 201, the round hole 3 is formed in the first heat-conducting plate 112, the sliding rod 301 is inserted into the round hole 3, the first heat-conducting plate 112 is convenient to slide on the sliding rod 301 when moving, the moving stability of the first heat-conducting plate 112 is improved, then the first heat-conducting plate 112 is provided with the threaded hole 303, the threaded rod 304 is connected with the internal threads of the threaded hole 303, one end of the threaded rod 304 is fixedly connected with the output end of the servo motor 307, the threaded rod 304 is enabled to rotate through the operation of the servo motor 307, and accordingly the first heat-conducting plate 112 is convenient to slide on the limiting block 201, and heat on the limiting block 201 is conducted.

As an implementation manner in this embodiment, according to fig. 8, the limiting assembly includes a limiting slot 4 formed on the first heat-conducting plate 112, a limiting plate 401 is disposed in the limiting slot 4, a bottom end of the limiting plate 401 is fixedly connected to the second heat-conducting plate 202, a plurality of groups of clamping slots 402 are formed on a top end surface of the limiting plate 401, a hinge seat 403 is fixedly mounted on the first heat-conducting plate 112, a rotating shaft 404 is rotatably connected to the hinge seat 403, the rotating shaft 404 is fixedly connected to the moving plate 405, a bottom end of the moving plate 405 is fixedly connected to a plugboard 406, a bottom end of the plugboard 406 is inserted into one of the clamping slots 402, a fixed block 407 is fixedly connected to the first heat-conducting plate 112, a top plate 408 is fixedly connected to the fixed block 407, a waist-shaped hole 409 is formed in the top plate 408, a fixed column 410 is slidably inserted into the waist-shaped hole 409, a bottom end of the fixed column 410 is fixedly connected to the moving plate 405, a baffle 412 is fixedly connected to a bottom end of the fixed column 410, a diameter of the baffle 412 is larger than a width of the waist-shaped hole 409, a bottom end of the fixed column 410 is provided with a second spring 413, and two ends of the second spring 405 are respectively fitted to the top ends of the fixed column 410.

Specifically, when the first heat-conducting plate 112 needs to be moved, the first heat-conducting plate 112 is provided with the limit groove 4, the limit groove 4 is internally provided with the limit plate 401, the limit plate 401 is provided with the clamping groove 402 through the movement of the first heat-conducting plate 112, the first heat-conducting plate 112 is fixedly connected with the hinge seat 403, the hinge seat 403 is rotationally connected with the rotating shaft 404, the rotating shaft 404 is fixedly connected with the moving plate 405, the bottom end of the moving plate 405 is fixedly connected with the inserting plate 406, the bottom end of the inserting plate 406 which is through the elastic force of the second spring 413 is inserted into one of the moving plates 405, when the first heat-conducting plate 112 needs to be moved, the moving plate 405 is moved through pulling the baffle plate 412, the inserting plate 406 is separated from the clamping groove 402 through the movement of the moving plate 405, so that the whole first heat-conducting plate 112 is conveniently moved, and the heat of the first heat-conducting plate 112 is conducted to the limiting blocks 201 in different areas.

The working principle of the invention is as follows: the four corners of the second heat-conducting plate 202 are provided with assembly holes 205, the second heat-conducting plate 202 is fixedly arranged on the surfaces of a plurality of groups of processors, so that the bottom end of the second heat-conducting plate 202 is attached to the processors, heat generated by the processors is conducted to the second heat-conducting plate 202, a limiting block 201 is fixedly arranged on the second heat-conducting plate 202, the heat of the second heat-conducting plate 202 is received through the limiting block 201, a first heat-conducting plate 112 is attached to the second heat-conducting plate 202, the limiting block 201 slides through a guide groove 2 on the first heat-conducting plate 112, the heat on the limiting block 201 is conveniently conducted to the first heat-conducting plate 112, a base 1 is attached to the first heat-conducting plate 112, the base 1 absorbs the heat which is received by the first heat-conducting plate 112, a heat-conducting pipe 106 is arranged on the base 1, copper pipes 107 are fixedly connected to the heat-conducting pipes 106, the base 1 conducts the heat to the heat-radiating fins 102 through the copper pipes 107, and the heat on the heat-radiating fins 102 is discharged through the operation of the fans 105;

when the guide groove 2 on the first heat-conducting plate 112 is required to slide on the limiting block 201, so that the first heat-conducting plate 112 is convenient to conduct all heat on the limiting block 201, a round hole 3 is formed in the first heat-conducting plate 112, a slide rod 301 is inserted into the round hole 3, the first heat-conducting plate 112 is convenient to slide on the slide rod 301 when moving, the moving stability of the first heat-conducting plate 112 is improved, a threaded hole 303 is formed in the first heat-conducting plate 112, a threaded rod 304 is connected with the internal threads of the threaded hole 303, one end of the threaded rod 304 is fixedly connected with the output end of the servo motor 307, the threaded rod 304 is rotated through the operation of the servo motor 307, so that the first heat-conducting plate 112 is convenient to slide on the limiting block 201, and heat on the limiting block 201 is conducted;

when the first heat-conducting plate 112 needs to be moved, a limit groove 4 is formed in the first heat-conducting plate 112, a limit plate 401 is arranged in the limit groove 4, a clamping groove 402 is formed in the limit plate 401 through movement of the first heat-conducting plate 112, a hinge seat 403 is fixedly connected to the first heat-conducting plate 112, a rotating shaft 404 is rotatably connected to the hinge seat 403, a movable plate 405 is fixedly connected to the rotating shaft 404, the bottom end of the movable plate 405 is fixedly connected with a plugboard 406, the bottom end of the plugboard 406 which is elastic by a second spring 413 is inserted into one of the movable plates 405, when the first heat-conducting plate 112 needs to be moved, the movable plate 405 is moved through pulling of a baffle plate 412, the plugboard 406 is separated from the clamping groove 402 through movement of the movable plate 405, and accordingly the whole first heat-conducting plate 112 is convenient to move, and heat of the first heat-conducting plate 112 is conducted to the limiting blocks 201 in different areas.

Finally, it should be noted that: the foregoing description is only illustrative of the preferred embodiments of the present invention, and although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements or changes may be made without departing from the spirit and principles of the present invention.

Claims (10)

1. The utility model provides a data center indirect evaporative cooling system, includes base (1), its characterized in that, the top surface of base (1) fixedly connected with radiating fin (102), the laminating of top middle-end position of radiating fin (102) has mount pad (103), the both sides rotation of mount pad (103) are connected with screw (104), the one end threaded connection of screw (104) is in on radiating fin (102), fixed mounting has fan (105) on mount pad (103), the inside fixed mounting of base (1) has a pair of heat pipe (106), a pair of heat pipe (106) one end fixedly connected with copper pipe (107), the other end of copper pipe (107) is inserted and is established in the inside of connecting block (108), the four corners position fixedly connected with bolt (109) of base (1), the cover is equipped with first spring (110) on bolt (109), the both ends of first spring (110) respectively with one side of bolt (109) and the top surface of bolt (108) are mutually laminated, the bottom of bolt (109) is connected on first connecting block (112);

still include installation component, adjusting part and spacing subassembly, installation component is used for cooperating base (1) and use, adjusting part is used for cooperating first heat-conducting plate (112) and use, spacing subassembly is used for cooperating base (1) is whole to use.

2. A data center indirect evaporative cooling heat sink system as in claim 1 wherein: the installation component is including seting up guide way (2) of the middle-end position in first heat-conducting plate (112) bottom, inside laminating of guide way (2) has stopper (201), stopper (201) fixed connection is on second heat-conducting plate (202).

3. A data center indirect evaporative cooling heat sink system as in claim 2 wherein: a first through hole (203) is formed in the limiting block (201), a second through hole (204) is formed in the bottom end of the second heat conducting plate (202), and the first through hole (203) and the second through hole (204) are communicated with each other.

4. A data center indirect evaporative cooling heat sink system as in claim 3 wherein: and the four corners of the second heat conducting plate (202) are provided with assembly holes (205).

5. A data center indirect evaporative cooling heat sink system as in claim 4 wherein: the adjusting component comprises a pair of round holes (3) formed in the first heat-conducting plate (112), a pair of sliding rods (301) are movably inserted into the round holes (3), two ends of each sliding rod (301) are fixedly connected with a butt joint seat (302), and the bottom ends of the butt joint seats (302) are fixedly connected to the second heat-conducting plate (202).

6. A data center indirect evaporative cooling heat sink system as in claim 5 wherein: threaded holes (303) are formed in the first heat-conducting plate (112), threaded rods (304) are connected to the threaded holes (303) in a threaded mode, limiting seats (305) are sleeved at one ends of the threaded rods (304), the bottom ends of the limiting seats (305) are fixedly connected to the second heat-conducting plate (202), supporting seats (306) are connected to the other ends of the threaded rods (304) in a rotating mode, and the bottom ends of the supporting seats (306) are fixedly connected to the second heat-conducting plate (202).

7. A data center indirect evaporative cooling heat sink system as in claim 6 wherein: one end of the threaded rod (304) is fixedly connected with the output end of the servo motor (307), and the servo motor (307) is fixedly arranged on the second heat conducting plate (202).

8. A data center indirect evaporative cooling heat sink system as in claim 7 wherein: the limiting assembly comprises a limiting groove (4) formed in the first heat-conducting plate (112), a limiting plate (401) is arranged in the limiting groove (4), the bottom end of the limiting plate (401) is fixedly connected to the second heat-conducting plate (202), and a plurality of groups of clamping grooves (402) are formed in the top end surface of the limiting plate (401).

9. A data center indirect evaporative cooling heat sink system as in claim 8 wherein: the hinge seat (403) is fixedly installed on the first heat-conducting plate (112), the hinge seat (403) is rotationally connected with a rotating shaft (404), the rotating shaft (404) is fixedly connected with a moving plate (405), the bottom end of the moving plate (405) is fixedly connected with a plugboard (406), and the bottom end of the plugboard (406) is inserted into one of the clamping grooves (402).

10. A data center indirect evaporative cooling heat sink system as in claim 9 wherein: fixedly connected with fixed block (407) on first heat-conducting plate (112), fixedly connected with roof (408) on fixed block (407), waist type hole (409) have been seted up on roof (408), the inside slip in waist type hole (409) is inserted and is equipped with fixed column (410), the diameter size of fixed column (410) is less than the width size in waist type hole (409), the bottom fixed connection of fixed column (410) is in on movable plate (405), the top fixedly connected with separation blade (412) of fixed column (410), the diameter size of separation blade (412) is greater than the width size in waist type hole (409), the cover is equipped with second spring (413) on fixed column (410), the both ends of second spring (413) do not with the top of movable plate (405) with the bottom of roof (408) laminating each other.