CN215735622U - Network server cabin heat dissipation hole structure - Google Patents

Abstract

The utility model discloses a network server cabin heat dissipation hole structure which comprises a shell and heat dissipation holes arranged on the shell and is characterized in that a mounting plate is mounted on the shell, an annular air channel edge is arranged on the mounting plate, a mounting seat is fixed on the shell, a baffle is rotatably connected to the mounting seat and shields the air channel edge through rotation, sliding grooves are formed in two opposite sides of the air channel edge, a sliding block is slidably connected in each sliding groove, the sliding direction of the sliding block is perpendicular to the axis direction of a rotating shaft of the baffle, a first hinging seat and a second hinging seat are respectively mounted on the bottom side surfaces of the sliding block and the baffle, a linkage rod is arranged between the first hinging seat and the second hinging seat and respectively hinged with the first hinging seat and the second hinging seat, and a driving structure for driving the sliding block to rotate is arranged on the air channel edge. The radiating structure can adjust or close the radiating holes, and when the network server engine room is not used, sundries are prevented from entering the inside of the network server engine room.

Description

Network server cabin heat dissipation hole structure

Technical Field

The utility model relates to the field of network server engine rooms, in particular to a heat dissipation hole structure of a network server engine room.

Background

The network server cabin is a box which is used for bearing communication electrical equipment and can install and arrange the electrical equipment in space according to the advantages of compactness, reasonability and the like.

Because the electrical elements in the network server engine room need heat dissipation when working, the heat dissipation holes are formed in the surface of the network server engine room, but the general heat dissipation holes are not adjustable, when the network server engine room is not used, the heat dissipation holes cannot be closed, and the situation that sundries enter the inside of the network server engine room is avoided.

Disclosure of Invention

In order to overcome the defects in the prior art, the utility model provides a heat dissipation hole structure of a network server cabin, which can adjust or close the heat dissipation hole and prevent sundries from entering the network server cabin when the network server cabin is not used.

In order to achieve the purpose, the heat dissipation hole structure of the network server cabin comprises a shell and heat dissipation holes arranged on the shell, and is characterized in that an installation plate is installed on the shell, an annular air channel edge is arranged on the installation plate, an installation seat is fixed on the shell, a baffle is connected to the installation seat in a rotating mode, the baffle shields the air channel edge through rotating, sliding grooves are formed in two opposite sides of the air channel edge, sliding blocks are connected to the sliding grooves in a sliding mode, the sliding direction of the sliding blocks is perpendicular to the axis direction of a rotating shaft of the baffle, a first hinging seat and a second hinging seat are installed on the sliding blocks and the bottom side surface of the baffle respectively, a linkage rod is arranged between the first hinging seat and the second hinging seat and hinged to the first hinging seat and the second hinging seat respectively, and a driving structure for driving the sliding blocks to rotate is arranged on the air channel edge.

Further, the drive structure sets up in one of them spout department, and the drive structure includes the screw rod and changes the handle, and the axis of screw rod sets up along the slip direction of slider, and the screw rod passes the slider, and screw rod and slider threaded connection, the screw rod rotate to be connected the wind channel along last, change handle and screw rod fixed connection.

Furthermore, the baffle is rotatably connected with a bolt block, a bolt rod is fixed on the air channel edge, the bolt block and the bolt rod are both positioned on one side of the air channel edge relative to the mounting seat, a bolt groove is formed in the bolt block, and the bolt block enables the bolt rod to be positioned in the bolt groove through rotation.

Further, the mounting plate is fixed to the housing by bolts.

Furthermore, the bolt block is provided with a spring plate in a rotating mode, a torsion spring is arranged between the spring plate and the bolt block, and the spring plate shields the bolt groove through rotation.

Has the advantages that: set up the baffle in the louvre position, make the slider remove along the spout through drive screw, the in-process that the slider removed, the slider passes through the gangbar drive baffle and rotates, and after the baffle rotates, the space between baffle and the louvre will change to can realize that the baffle closes the louvre, perhaps cover partial louvre, when the network server cabin does not use, shield the louvre completely through the baffle, avoid debris to enter into the network server cabin.

Drawings

The present invention will be further described and illustrated with reference to the following drawings.

FIG. 1 is a schematic overall block diagram of a preferred embodiment of the present invention;

FIG. 2 is a side view of a heat dissipating structure;

FIG. 3 is a top view of a heat dissipating structure with baffles hidden;

fig. 4 is a schematic view of the structure of the key block and key slot.

Reference numerals: 1. a housing; 2. heat dissipation holes; 3. mounting a plate; 4. an air duct edge; 5. a chute; 6. a slider; 7. a screw; 8. a first hinge mount; 9. a second hinge mount; 10. a linkage rod; 11. a bolt block; 12. a bolt rod; 13. a key slot; 14. a spring plate; 15. a torsion spring; 16. a baffle plate;

Detailed Description

The technical solution of the present invention will be more clearly and completely explained by the description of the preferred embodiments of the present invention with reference to the accompanying drawings.

As shown in fig. 1, the heat dissipation hole 2 structure of the network server cabin according to the preferred embodiment of the present invention includes a housing 1 and a heat dissipation hole 2 disposed on the housing 1, wherein a mounting plate 3 is mounted at the position of the heat dissipation hole 2, and the mounting plate 3 is mounted on the housing 1 by bolts. Be equipped with annular wind channel on the mounting panel 3 along 4, the wind channel is along 4 orientation louvres 2, and louvre 2's steam can be fixed with the mount pad through wind channel along 4 on the shell 1, rotates on the mount pad and is connected with baffle 16, and baffle 16 can shield the wind channel through rotating and follow 4 to make louvre 2's steam can't follow the wind channel and transmit along 4.

And a driving structure is arranged on the air duct edge 4 and used for driving the baffle 16 to rotate, so that the size of a gap opening between the baffle 16 and the air duct edge 4 is changed.

As shown in fig. 1 and 2, the driving structure includes sliding grooves 5 disposed on the upper surfaces of two opposite sides of the air duct 4, and sliding blocks 6 are slidably connected in the sliding grooves 5, and the sliding direction of the sliding blocks 6 is perpendicular to the axial direction of the rotating shaft of the baffle 16. A screw 7 is arranged in one of the sliding grooves 5, the screw 7 is rotatably connected to the air channel edge 4, the screw 7 penetrates through the sliding block 6 and is in threaded connection with the sliding block 6, one end of the screw 7 penetrates out of the air channel edge 4, and a rotating handle is fixed on one side of the screw penetrating out of the air channel edge 4. The screw 7 is rotated through the rotating handle, the screw 7 drives the sliding block 6 to move along the sliding groove 5 after being rotated, the upper surface of the sliding block 6 and the bottom side surface of the baffle 16 are respectively and fixedly provided with a first hinged seat 8 and a second hinged seat 9, a linkage rod 10 is arranged between the first hinged seat 8 and the second hinged seat 9, and two ends of the linkage rod 10 are respectively and rotatably connected to the first hinged seat 8 and the second hinged seat 9. When the sliding block 6 moves along the sliding groove 5, the sliding block 6 can drive the baffle 16 to rotate through the linkage rod 10, and after the baffle 16 rotates, the air duct edge 4 is opened and closed.

As shown in fig. 4, when the network server cabin is not in use and the heat dissipation holes 2 do not need to dissipate heat, the air duct edge 4 is shielded by the baffle 16. A bolt block 11 is rotatably connected to the baffle 16, a bolt rod 12 is fixed to the air channel edge 4, and both the bolt block 11 and the bolt rod 12 are located on one side of the air channel edge 4 opposite to the mounting seat.

The purpose of the baffle 16 to keep the air channel edge 4 closed can be achieved by the cooperation of the bolt block 11 and the bolt rod 12. Specifically, a bolt groove 13 is formed in the bolt block 11, after the air channel edge 4 is sealed by the baffle 16, the bolt block 11 is rotated, the bolt 12 is located in the bolt groove 13 in the process that the bolt groove 13 rotates along with the bolt block 11, and the diameter of the bolt 12 is almost equal to the width of the bolt groove 13. At this time, when the baffle 16 rotates again and opens the wind channel edge 4, the bolt 12 and the bolt groove 13 play a limiting role, so that the baffle 16 cannot be opened freely.

The bolt block 11 is provided with a spring piece 14 in a rotating mode, a torsion spring 15 is arranged between the spring piece 14 and the bolt block 11, the spring piece 14 shields the bolt groove 13 through rotation, one end of the torsion spring 15 is fixed with the bolt block 11, the other end of the torsion spring 15 is fixed with the spring piece 14, the spring piece 14 can keep shielding the bolt groove 13 under the elastic force action of the torsion spring 15, the bolt rod 12 needs to rotate into the bolt groove 13, a user needs to manually stir the spring piece 14, the bolt rod 12 enters the bolt groove 13, the spring piece 14 is loosened, the spring piece 14 is driven by the elastic force of the torsion spring 15 to seal the bolt groove 13 again, and the bolt rod 12 is prevented from sliding out of the bolt groove 13 randomly.

The above detailed description merely describes preferred embodiments of the present invention and does not limit the scope of the utility model. Without departing from the spirit and scope of the present invention, it should be understood that various changes, substitutions and alterations can be made herein by those skilled in the art without departing from the spirit and scope of the utility model as defined by the appended claims and their equivalents. The scope of the utility model is defined by the claims.

Claims (5)

1. A heat dissipation hole structure of a network server cabin comprises a shell and heat dissipation holes arranged on the shell, and is characterized in that a mounting plate is arranged on the shell, an annular air channel edge is arranged on the mounting plate, a mounting seat is fixed on the shell, a baffle is rotatably connected on the mounting seat and shields the air channel edge through rotation,

the air duct is provided with sliding grooves along two opposite sides, a sliding block is connected in the sliding grooves in a sliding mode, the sliding direction of the sliding block is perpendicular to the axis direction of the rotating shaft of the baffle, a first hinged seat and a second hinged seat are respectively installed on the surface of the bottom side of the sliding block and the surface of the bottom side of the baffle, a linkage rod is arranged between the first hinged seat and the second hinged seat and is hinged to the first hinged seat and the second hinged seat respectively, and a driving structure for driving the sliding block to rotate is arranged on the air duct edge.

2. The heat dissipation hole structure of the network server cabin as claimed in claim 1, wherein the driving structure is disposed at one of the sliding grooves, the driving structure includes a screw rod and a rotating handle, an axis of the screw rod is disposed along a sliding direction of the slider, the screw rod passes through the slider and is in threaded connection with the slider, the screw rod is rotatably connected to the air duct, and the rotating handle is fixedly connected to the screw rod.

3. The heat dissipation hole structure of the network server cabin as claimed in claim 1, wherein a latch block is rotatably connected to the baffle, a latch rod is fixed on the air duct edge, the latch block and the latch rod are both located on a side of the air duct edge opposite to the mounting seat, a latch slot is formed in the latch block, and the latch block enables the latch rod to be located in the latch slot through rotation.

4. The network server nacelle louvers structure of claim 1, wherein the mounting plate is bolted to the housing.

5. The heat dissipation hole structure of the network server cabin as claimed in claim 4, wherein the bolt block is provided with a spring piece in a rotating manner, a torsion spring is arranged between the spring piece and the bolt block, and the spring piece shields the bolt slot through rotation.

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