CN114442776B - Efficient heat dissipation structure of edge computing host - Google Patents

Abstract

The invention discloses a high-efficiency heat dissipation structure of an edge computing host, which relates to the technical field of computers and comprises a heat dissipation plate, wherein the lower end of the heat dissipation plate is provided with a computer body, one side of the computer body is provided with an end plate, one side of the end plate is provided with a communication port, one side of the end plate is provided with a display screen, the interior of the computer body is provided with a fan, and the outer side of the computer body is provided with a guide structure; in the use of heating panel and computer body, guide structure avoids evacuated heat to get into the computer body at the secondary to improve radiating efficiency, at heating panel and computer body installation, installation component improves the practicality of heating panel and computer body, in the long-term use of computer body, and the dismantlement structure makes the air inlet board dismantle fast, thereby clears up the inside dust of aviation baffle, thereby improves the radiating effect.

Description

Efficient heat dissipation structure of edge computing host

Technical Field

The invention relates to the technical field of computers, in particular to a high-efficiency heat dissipation structure of an edge computing host.

Background

The existing efficient heat dissipation structure of the edge computing host has certain defects, firstly, in the use process of a computer body, heat is dissipated in the process of heat dissipation, the heat is easy to be absorbed by the computer body at the second time around the computer body, the heat dissipation effect is poor, secondly, the heat dissipation plate and the computer body are installed in the installation process, under different installation conditions, the heat dissipation plate cannot be assembled and disassembled in a selected mode, the disassembly is inconvenient, finally, the air inlet plate is used as an air flow inlet port, dust inside the air inlet plate is easy to accumulate under long-term use, and therefore the heat dissipation effect is reduced.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides a high-efficiency heat dissipation structure of an edge computing host, and solves the problems in the background art.

In order to achieve the above purpose, the invention is realized by the following technical scheme: the efficient heat dissipation structure of the edge computing host comprises a heat dissipation plate, wherein the lower end of the heat dissipation plate is provided with a computer body, one side of the computer body is provided with an end plate, one side of the end plate is provided with a communication port, one side of the end plate is provided with a display screen, the inside of the computer body is provided with a fan, the outside of the computer body is provided with a guide structure, the outside of the computer body is provided with a heat dissipation hole, the lower end of the computer body is provided with an air inlet plate, the joint of the heat dissipation plate and the computer body is provided with an installation assembly, the tail end of the computer body is provided with a power interface, and the joint of the computer body and the air inlet plate is provided with a disassembly structure;

The guide structure comprises an air duct, an air inlet is formed in one side of the air duct, an air outlet is formed in the tail end of the air duct, a mounting column is arranged on one side of the air duct, a clamping block is arranged on one side of the mounting column, and a mounting hole is formed in one side of the computer body;

The installation component includes the spliced pole, the one end of spliced pole is provided with the limiting plate, the spread groove has been seted up to the upper end of computer body, the inboard of spread groove is provided with the spring, one side of spring is provided with the auxiliary block.

As a further technical scheme of the invention, the heat radiating plate and the computer body are movably connected through the mounting component, the computer body is fixedly connected with the end plate, the width of the end plate is larger than that of the computer body, a handle is mounted on the outer surface of one side of the end plate, and the handle is of a C-shaped structure.

As a further technical scheme of the invention, the communication port and the display screen are electrically connected with the computer body, the display screen is of a rectangular structure, the fans are electrically connected with the computer body, the fans are symmetrically distributed in a plurality of groups, the heat dissipation holes are communicated with the computer body, and the power interface is electrically connected with the computer body.

As a further technical scheme of the invention, the number of the air guide cylinders is two, the air guide cylinders are symmetrically distributed, the air guide cylinders are of hollow structures, the side cross section area of the air inlet is smaller than that of the air guide cylinders, and the air guide cylinders are communicated with the air inlet.

As a further technical scheme of the invention, the number of the air outlets is two, the air outlets are symmetrically distributed, the mounting columns and the air duct are fixedly connected, the number of the mounting columns is a plurality of groups and are distributed in an array, the mounting columns and the clamping blocks are fixedly connected, the clamping blocks are of elastic structures, the diameter of the clamping blocks is larger than that of the mounting columns, the mounting holes are communicated with the computer body, and the diameter of the mounting holes is larger than that of the mounting columns and smaller than that of the clamping blocks.

As a further technical scheme of the invention, the number of the connecting columns is four groups and the connecting columns are distributed in an array, the connecting columns are fixedly connected with the radiating plate, the connecting columns are fixedly connected with the limiting plates, the limiting plates and the connecting columns are made of aluminum magnesium alloy, the length of the limiting plates is larger than that of the connecting columns, and the combination of the connecting columns and the limiting plates is matched with the connecting grooves.

As a further technical scheme of the invention, the number of the springs is four groups and distributed in an array, one end of each spring is fixedly connected with the connecting groove, the other ends of the auxiliary blocks are fixedly connected with the other ends of the springs, the number of the auxiliary blocks is four groups and distributed in an array, the auxiliary blocks are of arc structures, and the outer surfaces of the inner rings of the auxiliary blocks are matched with the edges of the limiting plates.

As a further technical scheme of the invention, the dismounting structure comprises a hinge, the lower end of the computer body is provided with a rotating handle, the inner side of the computer body is provided with a movable groove, the upper end of the rotating handle is provided with a rotating pin, and one side of the air inlet plate is provided with a limiting groove.

As a further technical scheme of the invention, the number of the hinges is three, the hinges are distributed in an array, the number of the rotating handles is two, the rotating handles are symmetrically distributed, the bottoms of the rotating handles are made of rubber materials, the side sections of the movable grooves are of L-shaped structures rotating by 90 degrees, and the number of the movable grooves is two, and the movable grooves are symmetrically distributed.

As a further technical scheme of the invention, the rotating pin and the rotating handle are fixedly connected, the side section of the rotating pin is of an L-shaped structure, the number of the limiting grooves is two, the limiting grooves are symmetrically distributed, the cross sections of the limiting grooves are of semicircular structures, and the limiting grooves are matched with the rotating pin.

Advantageous effects

The invention provides an efficient heat dissipation structure of an edge computing host. Compared with the prior art, the method has the following beneficial effects:

1. The utility model provides an edge calculates high-efficient heat radiation structure of host computer, in heating panel and computer body use, the user installs air duct and computer body, through the erection column and the fixture block with air duct one side remove along the mounting hole in the computer body outside, make the fixture block take place deformation, until the inside of extrusion to the mounting hole, under the supporting role through the erection column, make air duct and the outside of computer body laminate, install the air duct, make the air intake laminate with the outside of louvre, at computer body operation in-process, the fan dispels the heat, make the wind stream get into the inside of computer body through the air inlet plate, it is sparse along air intake and air outlet through the louvre with the inside hot-blast of computer body through the fan, make the inside heat of computer body keep away from the air inlet plate in transportation, avoid the heat of evacuation to get into the computer body through the air inlet plate, thereby improve radiating efficiency.

2. The utility model provides an edge calculates high-efficient heat radiation structure of host computer, at heating panel and computer body installation, under the installation condition of difference, the user can dismantle the selection with the heating panel and join in marriage, the user is through removing spliced pole and limiting plate for the spliced pole and limiting plate's combination is removed along the inside of spread groove, under the spacing effect of spread groove, makes the spring remove, and the spread groove compresses simultaneously, until break away from the inside of spread groove with the limiting plate, dismantle the heating panel, the installation is the same, improve the practicality of heating panel and computer body.

3. The utility model provides an edge calculates high-efficient heat radiation structure of host computer, in the long-term use of computer body, the inside of air inlet board produces the piling up of dust easily, the clearance is inconvenient, the user will be through rotating the twist grip for the twist grip drives the rotation round pin and rotates along the inboard surface of movable groove and spacing groove, until the rotation round pin breaks away from the inboard surface of spacing groove, the same way another group of twist grip all dismantles with the same kind of mode, finally under the connection through the hinge, make the air inlet board dismantle, thereby the inside dust of clearance air inlet board, thereby improve the radiating effect.

Drawings

FIG. 1 is a schematic diagram of a high-efficiency heat dissipation structure of an edge computing host;

FIG. 2 is a schematic diagram of a portion of a high-efficiency heat dissipation structure of an edge computing host;

FIG. 3 is a partial exploded view of a guiding structure in a high efficiency heat dissipating structure of an edge computing host;

FIG. 4 is an enlarged view of the high efficiency heat dissipating structure of the edge computing host of FIG. 3A;

FIG. 5 is a partial exploded view of a heat spreader plate and a computer body in a high efficiency heat dissipation structure for an edge computing host;

FIG. 6 is another view of the efficient heat dissipation structure of the edge computing host of FIG. 1;

fig. 7 is a partial side cross-sectional view of a computer body and air intake plate in a high efficiency heat dissipating structure of an edge computing host.

In the figure: 1. a heat dissipation plate; 2. a computer body; 3. an end plate; 4. a communication port; 5. a display screen; 6. a handle; 7. a fan; 8. a guide structure; 81. an air duct; 82. an air inlet; 83. an air outlet; 84. a mounting column; 85. a clamping block; 86. a mounting hole; 9. a heat radiation hole; 10. an air inlet plate; 11. a mounting assembly; 111. a connecting column; 112. a limiting plate; 113. a connecting groove; 114. a spring; 115. an auxiliary block; 12. a power interface; 13. disassembling the structure; 131. a hinge; 132. rotating the handle; 133. a movable groove; 134. a rotation pin; 135. and a limit groove.

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 to 7, the present invention provides a technical solution of a high-efficiency heat dissipation structure of an edge computing host: the utility model provides a high-efficient heat radiation structure of edge computing host, including heating panel 1, heating panel 1's lower extreme is provided with computer body 2, one side of computer body 2 is provided with end plate 3, one side of end plate 3 is provided with communication port 4, one side of end plate 3 is provided with display screen 5, the inside of computer body 2 is provided with fan 7, computer body 2's outside is provided with guide structure 8, louvre 9 has been seted up in computer body 2's outside, computer body 2's lower extreme is provided with air inlet plate 10, heating panel 1 and computer body 2's junction is provided with installation component 11, computer body 2's tail end is provided with power interface 12, computer body 2 and air inlet plate 10's junction is provided with dismantlement structure 13, guide structure 8 includes air duct 81, air duct 81's one side has seted up air intake 82, air duct 81's tail end has been seted up air outlet 83, one side of air duct 81 is provided with erection column 84, one side of erection column 84 is provided with fixture block 85, installation hole 86 has been seted up on one side of computer body 2, installation component 11 includes spliced pole 111, one end of spliced pole 111 is provided with air inlet plate 10, the upper end of computer body 2 has been provided with air inlet plate 113, the junction box 113 has been set up at the end of computer body 2, the end of spliced bin 132 has been provided with air inlet port 13, the end of air duct 132 has been set up in the air duct 132, the end has been set up in the air duct 132, and the end of air duct 132 has been set up has been provided with air inlet port 132, and the end of air duct 132 has been set has been provided with air outlet port has a stand-down by the air outlet has been provided by the air.

Referring to fig. 1-2, further, the heat dissipation plate 1 and the computer body 2 are movably connected through the mounting assembly 11, the computer body 2 and the end plate 3 are fixedly connected, the width of the end plate 3 is larger than that of the computer body 2, a handle 6 is mounted on one side outer surface of the end plate 3, the handle 6 is in a C-shaped structure, the communication port 4 and the display screen 5 are electrically connected with the computer body 2, the display screen 5 is in a rectangular structure, the fans 7 are electrically connected with the computer body 2, the fans 7 are symmetrically distributed in number, the heat dissipation holes 9 are communicated with the computer body 2, and the power interface 12 is electrically connected with the computer body 2.

Referring to fig. 2-4, the number of air ducts 81 is two, the air ducts 81 are in a hollow structure, the side cross-sectional area of the air inlet 82 is smaller than the side cross-sectional area of the air ducts 81, the air ducts 81 and the air inlets 82 are communicated, the number of air outlets 83 is two, the air ducts 81 are in symmetrical distribution, the mounting columns 84 are fixedly connected with the air ducts 81, the number of the mounting columns 84 is a plurality of groups and are in array distribution, the mounting columns 84 are fixedly connected with the clamping blocks 85, the clamping blocks 85 are in elastic structures, the diameter of the clamping blocks 85 is larger than that of the mounting columns 84, the mounting holes 86 are communicated with the computer body 2, and the diameter of the mounting holes 86 is larger than that of the mounting columns 84 and smaller than that of the clamping blocks 85.

Referring to fig. 5, the number of the connecting columns 111 is four and distributed in an array, the connecting columns 111 and the heat dissipation plate 1 are fixedly connected, the connecting columns 111 and the limiting plates 112 are fixedly connected, the limiting plates 112 and the connecting columns 111 are made of aluminum magnesium alloy, the length of the limiting plates 112 is greater than that of the connecting columns 111, the combination of the connecting columns 111 and the limiting plates 112 is matched with the connecting grooves 113, the number of the springs 114 is four and distributed in an array, one end of each spring 114 is fixedly connected with the connecting grooves 113, the other ends of the auxiliary blocks 115 and the springs 114 are fixedly connected, the number of the auxiliary blocks 115 is four and distributed in an array, the auxiliary blocks 115 are of arc-shaped structures, and the outer surfaces of the inner rings of the auxiliary blocks 115 are matched with the edges of the limiting plates 112.

Referring to fig. 6-7, the number of hinges 131 is three, the number of rotating handles 132 is two, the rotating handles 132 are symmetrically distributed, the bottom of the rotating handles 132 is made of rubber, the side sections of the movable slots 133 are of an L-shaped structure rotating by 90 degrees, the number of the movable slots 133 is two, the rotating pins 134 and the rotating handles 132 are fixedly connected, the side sections of the rotating pins 134 are of an L-shaped structure, the number of the limiting slots 135 is two, the limiting slots 135 are symmetrically distributed, the cross sections of the limiting slots 135 are of a semicircular structure, and the limiting slots 135 and the rotating pins 134 are matched.

The working principle of the invention is as follows: in the use of the heat dissipation plate 1 and the computer body 2, a user installs the air duct 81 and the computer body 2, through moving the mounting column 84 and the clamping block 85 on one side of the air duct 81 along the mounting hole 86 on the outer side of the computer body 2, the clamping block 85 deforms until being extruded to the inside of the mounting hole 86, under the supporting effect of the mounting column 84, the air duct 81 is attached to the outer side of the computer body 2, the air duct 81 is installed, the air inlet 82 is attached to the outer side of the heat dissipation hole 9, in the operation process of the computer body 2, the fan 7 dissipates heat, so that air flows into the inside of the computer body 2 through the air inlet 10, and the air inside the computer body 2 is evacuated through the air inlet 82 and the air outlet 83 through the fan 7, so that the heat inside the computer body 2 is far away from the air inlet 10 in the transportation process, the evacuated heat is prevented from entering the computer body 2 through the air inlet 10, and the heat dissipation efficiency is improved.

It should be noted that, in the installation process of the heat dissipation plate 1 and the computer body 2, under different installation conditions, a user can detach the heat dissipation plate 1, and the user moves the connection post 111 and the limiting plate 112 through moving the connection post 111 and the limiting plate 112, so that the combination of the connection post 111 and the limiting plate 112 moves along the inside of the connection groove 113, and under the limiting effect of the connection groove 113, the spring 114 moves, and meanwhile, the connection groove 113 compresses until the limiting plate 112 is separated from the inside of the connection groove 113, so that the heat dissipation plate 1 is detached, and the installation is the same, thereby improving the practicability of the heat dissipation plate 1 and the computer body 2.

It should be noted that, in the long-term use process of the computer body 2, dust is easily accumulated in the air inlet plate 10, cleaning is inconvenient, a user rotates the rotating handle 132, so that the rotating handle 132 drives the rotating pin 134 to rotate along the inner side and the outer surface of the movable groove 133 and the limiting groove 135 until the rotating pin 134 is separated from the inner side and the outer surface of the limiting groove 135, the rotating handles 132 of the other group are detached in the same mode, and finally the air inlet plate 10 is detached through the connection of the hinge 131, so that dust in the air inlet plate 10 is cleaned, and the heat dissipation effect is improved.

Claims (7)

1. The utility model provides a high-efficient heat radiation structure of edge calculation host computer, includes heating panel (1), its characterized in that, the lower extreme of heating panel (1) is provided with computer body (2), one side of computer body (2) is provided with end plate (3), one side of end plate (3) is provided with communication port (4), one side of end plate (3) is provided with display screen (5), the inside of computer body (2) is provided with fan (7), the outside of computer body (2) is provided with guide structure (8), louvre (9) have been seted up in the outside of computer body (2), the lower extreme of computer body (2) is provided with into aerofoil (10), the junction of heating panel (1) and computer body (2) is provided with installation component (11), the tail end of computer body (2) is provided with power source (12), the junction of computer body (2) and air inlet foil (10) is provided with dismantles structure (13).

The guide structure (8) comprises an air duct (81), an air inlet (82) is formed in one side of the air duct (81), an air outlet (83) is formed in the tail end of the air duct (81), a mounting column (84) is arranged on one side of the air duct (81), a clamping block (85) is arranged on one side of the mounting column (84), and a mounting hole (86) is formed in one side of the computer body (2);

The mounting assembly (11) comprises a connecting column (111), one end of the connecting column (111) is provided with a limiting plate (112), the upper end of the computer body (2) is provided with a connecting groove (113), the inner side of the connecting groove (113) is provided with a spring (114), and one side of the spring (114) is provided with an auxiliary block (115);

the number of the air outlets (83) is two, the two air outlets are symmetrically distributed, the mounting columns (84) and the air guide cylinder (81) are fixedly connected, the number of the mounting columns (84) is a plurality of groups and are distributed in an array, the mounting columns (84) and the clamping blocks (85) are fixedly connected, the clamping blocks (85) are elastic structures, the diameter of each clamping block (85) is larger than that of each mounting column (84), the mounting holes (86) are communicated with the computer body (2), and the diameter of each mounting hole (86) is larger than that of each mounting column (84) and smaller than that of each clamping block (85);

The number of the connecting columns (111) is four, the connecting columns (111) and the radiating plates (1) are distributed in an array, the connecting columns (111) and the radiating plates (1) are fixedly connected, the connecting columns (111) and the limiting plates (112) are fixedly connected, the limiting plates (112) and the connecting columns (111) are made of aluminum magnesium alloy, the length of the limiting plates (112) is greater than that of the connecting columns (111), and the combination of the connecting columns (111) and the limiting plates (112) is matched with the connecting grooves (113);

The number of the springs (114) is four groups and is distributed in an array, one end of each spring (114) is fixedly connected with the corresponding connecting groove (113), the other ends of the auxiliary blocks (115) and the springs (114) are fixedly connected, the number of the auxiliary blocks (115) is four groups and is distributed in an array, the auxiliary blocks (115) are of arc-shaped structures, and the outer surface of the inner ring of each auxiliary block (115) is matched with the edge of the limiting plate (112).

2. The efficient heat dissipation structure of the edge computing host machine according to claim 1, wherein movable connection is formed between the heat dissipation plate (1) and the computer body (2) through a mounting assembly (11), the computer body (2) and the end plate (3) are fixedly connected, the width of the end plate (3) is larger than that of the computer body (2), a handle (6) is mounted on the outer surface of one side of the end plate (3), and the handle (6) is of a C-shaped structure.

3. The efficient heat dissipation structure of an edge computing host according to claim 1, wherein the communication port (4) and the display screen (5) are electrically connected with the computer body (2), the display screen (5) is of a rectangular structure, the fans (7) are electrically connected with the computer body (2), the fans (7) are in a plurality of groups and are symmetrically distributed, the heat dissipation holes (9) are communicated with the computer body (2), and the power interface (12) is electrically connected with the computer body (2).

4. The efficient heat dissipation structure of an edge computing host machine according to claim 1, wherein the number of the air guide cylinders (81) is two, the air guide cylinders (81) are of hollow structures, the side cross-sectional area of the air inlet (82) is smaller than that of the air guide cylinders (81), and the air guide cylinders (81) are communicated with the air inlet (82).

5. The efficient heat dissipation structure of an edge computing host machine according to claim 1, wherein the dismounting structure (13) comprises a hinge (131), a rotating handle (132) is arranged at the lower end of the computer body (2), a movable groove (133) is formed in the inner side of the computer body (2), a rotating pin (134) is arranged at the upper end of the rotating handle (132), and a limit groove (135) is formed in one side of the air inlet plate (10).

6. The efficient heat dissipation structure of an edge computing host machine according to claim 5, wherein the number of the hinges (131) is three, the hinges are distributed in an array, the number of the rotating handles (132) is two, the rotating handles (132) are symmetrically distributed, the bottoms of the rotating handles (132) are made of rubber materials, the side sections of the movable grooves (133) are of an L-shaped structure rotated by 90 degrees, and the number of the movable grooves (133) is two, and the movable grooves are symmetrically distributed.

7. The efficient heat dissipation structure of an edge computing host machine according to claim 5, wherein the rotation pins (134) and the rotation handles (132) are fixedly connected, the side sections of the rotation pins (134) are of an L-shaped structure, the number of the limit grooves (135) is two, the limit grooves are symmetrically distributed, the cross sections of the limit grooves (135) are of semicircular structures, and the limit grooves (135) are matched with the rotation pins (134).