CN115113702B - Graphic processing device for asymmetric graphic compression transmission - Google Patents

Abstract

The invention discloses a graphic processing device for asymmetric graphic compression transmission, which comprises: the front cover is fixed with the graphic processing device shell through the screw, and the surface mounting of front cover has the stationary blade, installs the dust separation net on the stationary blade simultaneously, and front cover surface mounting has the display screen, and the display screen and the air quantity sensor electric connection on the front cover, and the inside spiro union of graphic processing device shell has outside barrel, and the inside and the air inlet section of thick bamboo fixed connection of outside barrel, the inside fixed air inlet regulation structure that is provided with of air inlet section of thick bamboo. The graphic processing device for asymmetric graphic compression transmission has the advantages that the air inlet adjusting structure is arranged, so that the air inlet of the cooling fan can be adjusted, and the air inlet of the air inlet adjusting structure is in a maximum state in summer; in the eastern season, the air inlet quantity of the air inlet adjusting structure is in the lowest state, so that the condition that the CPU temperature is too low due to the fact that the air inlet quantity of the air inlet adjusting structure is too large in winter is avoided.

Description

Graphic processing device for asymmetric graphic compression transmission

Technical Field

The invention relates to the field of graphic processing, in particular to a graphic processing device for asymmetric graphic compression transmission.

Background

The symmetrical transmission protocol means that the network uplink and downloading speeds are the same; the uplink speed and the downloading speed are different, and generally, the current use of the method is an asymmetric transmission protocol, and the downloading speed is generally higher than the uplink speed, so that when the graphic processing device operates, the heat dissipation capacity of the computer host is large, accessories are easy to damage, and the CPU for graphic processing has the problem of thermal damage.

In order to radiate the CPU in the prior art, a radiating fan for radiating one side of the CPU is arranged in the case, and other heat in the case can be directly blown to the CPU by the radiating fan in the actual blowing process, so that the radiating effect of the CPU is ensured, the CPU is provided with an independent radiating component, the influence of other heat sources in the case can not be received, and the efficient radiating effect is achieved.

To solve the above-mentioned problems, the patent with publication number CN216118620U discloses a graphic processing device for asymmetric graphic compression transmission, and proposes "comprising a CPU protection component with a graphic processing host housing disposed on an inner wall of the graphic processing host housing and a heat dissipation component for cooling the graphic processing CPU; when the heat dissipation component dissipates heat to the graphic processing CPU, the size of the cold air inlet cannot be adjusted, and when the air inlet quantity cannot be adjusted down in cold weather in winter, the temperature of the graphic processing CPU is too low to work.

In view of the above, intensive studies have been conducted to solve the above problems.

Disclosure of Invention

The invention provides a graphic processing device for asymmetric graphic compression transmission, which aims to make up market blank.

The present invention is directed to a graphic processing apparatus for asymmetric graphic compression transmission, which solves the above-mentioned problems of the prior art.

In order to achieve the above purpose, the present invention provides the following technical solutions: a graphic processing apparatus for asymmetric graphic compression transmission, comprising:

the front cover is fixed with the image processing device shell through a screw, a fixing sheet is arranged on the surface of the front cover, a dust-proof net is arranged on the fixing sheet at the same time, a display screen is arranged on the surface of the front cover, the display screen on the front cover is electrically connected with the air quantity sensor, an outer cylinder body is in threaded connection with the interior of the image processing device shell, the interior of the outer cylinder body is fixedly connected with the air inlet cylinder, an air inlet adjusting structure is fixedly arranged in the air inlet cylinder, the air quantity sensor is fixedly arranged on the right side of the interior of the air inlet cylinder, a cooling fan is fixedly arranged on the left side of the interior of the air inlet cylinder, a connecting ring is arranged on the inner side of a mounting ring on the air inlet adjusting structure, a wind shield is arranged on the inner side of the connecting ring, an air through hole is formed in the wind shield, and the air through the wind shield is covered; the outer side of the front cover is provided with a limit groove, a limit strip is inserted into the limit groove, the limit strip is welded on the right side surface of the fixing piece, and the surface of the front cover is provided with two groups of stress grooves;

the image processing device comprises a graphics processing device shell, wherein a circuit main board is arranged on the inner side wall of the graphics processing device shell in a threaded mode, a CPU is embedded on the circuit main board, and meanwhile the CPU is contacted with a radiator through silicone grease.

Further, the sections of the air inlet cylinder and the outer cylinder are of concentric circle structures, the sections of the air inlet cylinder and the outer cylinder which are combined together are arranged in a concave shape, and meanwhile, the right side of the inner part of the outer cylinder is provided with an air outlet which is opposite to the radiator.

Further, eight groups of heat dissipation air outlet holes are uniformly formed in the circumferential position of the right side surface of the outer side cylinder body, heat dissipation holes are formed in the shell of the image processing device, and the heat radiator and the heat dissipation air outlet holes are arranged oppositely.

Further, the air inlet adjusting structure comprises a mounting ring, a connecting column, a sliding block, a sliding groove, a connecting ring, a guide column, a connecting sheet, a groove, an air-permeable opening, a wind shield, a connecting rod and a stress column.

Further, the collar welds with an air inlet section of thick bamboo together, and four sets of spouts have evenly been seted up to the inner wall circumference position of collar, and the spout looks adaptation of size with the slider, and the slider slides simultaneously and sets up in the inside of spout.

Further, the profile of slider and spout is the dovetailed setting, and the slider sets up to four groups evenly installs in the outside circumference position of go-between, and four groups of spliced poles are evenly installed to the inner wall circumference position of go-between.

Further, the wind shielding plates are uniformly arranged into four groups, the air ventilation openings are uniformly arranged on the surfaces of the wind shielding plates into four groups, the air ventilation openings are blocked through the wind shielding plates, and the air ventilation openings and the wind shielding plates are all fan-shaped.

Further, the connecting piece is a cross-shaped structure made of metal materials, four groups of wind shields are uniformly arranged on the outer side of the connecting piece, and the four groups of wind shields are all rotary structures taking the connecting piece as a circle center.

Furthermore, four groups of mounting grooves are uniformly formed in the wind shield, guide posts in arc-shaped arrangement are mounted in the four groups of mounting grooves, and the guide posts are inserted into guide blocks at the bottom of the connecting post.

Furthermore, the radiator is fixed on the circuit main board through the mounting buckle, and comprises radiating fins and a fixing column, wherein a plurality of groups of radiating fins are uniformly arranged at the peripheral positions of the outer sides of the fixing column, and the cross sections of the radiating fins are arranged in an S shape.

Compared with the prior art, the invention has the beneficial effects that:

1. the air inlet adjusting structure is arranged to adjust the air inlet of the cooling fan, and the air inlet of the air inlet adjusting structure is in a maximum state in summer; in the eastern season, the air inlet quantity of the air inlet regulating structure is in the lowest state, so that the condition that the CPU temperature is too low due to the fact that the air inlet quantity of the air inlet regulating structure is too large in winter is avoided;

2. the handheld atress post drives the go-between through the connecting rod for the go-between moves the spliced pole and rotates with the windshield, and the windshield removes from the ventilative mouth, changes the air output of windshield through the coverage area of change windshield to the ventilative mouth.

Drawings

FIG. 1 is a schematic elevational view of the structure of the present invention;

FIG. 2 is a side view of the structure of FIG. 1 of the present invention;

FIG. 3 is a schematic view of an air intake adjusting structure of the present invention;

FIG. 4 is a schematic view of section A-A of FIG. 3 of the structure of the present invention;

FIG. 5 is a schematic view showing the vent of the structure of the present invention in a released state;

FIG. 6 is a schematic diagram of a heat sink fin according to the present invention;

fig. 7 is a three-dimensional view of a heat sink fin of the structure of the present invention;

fig. 8 is a three-dimensional view of a wind shield of the structure of the present invention.

In the figure: 1. a front cover; 2. a stress groove; 3. a fixing piece; 4. a limit bar; 5. a dust-separating net; 6. an air inlet cylinder; 7. an outer cylinder; 8. an air inlet adjusting structure; 80. a mounting ring; 81. a connecting column; 82. a slide block; 83. a chute; 84. a connecting ring; 85. a guide post; 86. a connecting sheet; 87. slotting; 88. an air ventilation port; 89. a wind shielding sheet; 90. a wind deflector; 91. a connecting rod; 92. a stress column; 9. an air volume sensor; 10. an air outlet; 11. installing a buckle; 12. a heat sink; 13. a circuit motherboard; 14. a CPU; 15. a graphics processing apparatus housing; 16. a heat radiation fin; 17. and fixing the column.

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.

The first embodiment is as follows: referring to fig. 1-8, the present invention provides a technical solution: a graphic processing apparatus for asymmetric graphic compression transmission, comprising: a front cover 1 and a graphic processing apparatus housing 15;

the front cover 1 and the image processing device shell 15 are fixed through screws, a fixing sheet 3 is arranged on the surface of the front cover 1, a dust-proof net 5 is arranged on the fixing sheet 3, a display screen is arranged on the surface of the front cover 1, the display screen on the front cover 1 is electrically connected with an air quantity sensor 9, an outer cylinder 7 is in threaded connection with the inside of the image processing device shell 15, the inside of the outer cylinder 7 is fixedly connected with an air inlet cylinder 6, an air inlet adjusting structure 8 is fixedly arranged in the air inlet cylinder 6, an air quantity sensor 9 is fixedly arranged on the right side of the inside of the air inlet cylinder 6, a cooling fan is fixedly arranged on the left side of the inside of the air inlet cylinder 6, a connecting ring 84 is arranged on the inner side of a mounting ring 80 on the air inlet adjusting structure 8, a wind shield 90 is arranged on the inner side of the connecting ring 84, an air through hole 88 is formed in the wind shield 90, and the air through the wind shield 89 is covered; the outer side of the front cover 1 is provided with a limit groove, a limit strip 4 is inserted into the limit groove, the limit strip 4 is welded on the right side surface of the fixing piece 3, and the surface of the front cover 1 is provided with two groups of stress grooves 2;

the inner side wall of the casing 15 of the image processing device is provided with a circuit main board 13 in a screwed mode, the circuit main board 13 is provided with a CPU14 in an embedded mode, and the CPU14 is contacted with the radiator 12 through silicone grease.

When the CPU14 performs the graphics processing, the generated heat is transferred to the radiator 12, the air flow accelerated by the cooling fan is ejected from the air outlet 10 and is ejected onto the surface of the radiator 12, the cooling purpose of the CPU14 is achieved by performing air cooling and heat dissipation on the radiator 12, and the hot air is ejected through eight groups of heat dissipation air outlet holes on the outer side of the outer cylinder 7 and is ejected through air holes on the graphics processing device housing 15.

The second embodiment is as follows: the present embodiment is further limited to the first embodiment, the sections of the air inlet cylinder 6 and the outer cylinder 7 are concentric, the combined sections of the air inlet cylinder 6 and the outer cylinder 7 are concave, and the air outlet 10 is formed in the right side of the inner part of the outer cylinder 7, and the air outlet 10 is opposite to the radiator 12.

As shown in fig. 1: the air outlet 10 is opposite to the radiator 12, and the air flow ejected from the air outlet 10 impinges on the radiator 12 to perform air cooling and heat dissipation on the radiator 12, so as to improve the working efficiency of the CPU 14.

And a third specific embodiment: in this embodiment, as a further limitation of the second embodiment, eight groups of heat dissipation air outlet holes are uniformly formed in the circumferential position of the right side surface of the outer cylinder 7, and the heat dissipation holes are formed in the casing 15 of the graphics processing apparatus, and the heat sink 12 is disposed opposite to the heat dissipation air outlet holes.

As shown in fig. 1: eight groups of heat dissipation air outlet holes are uniformly formed in the circumferential position of the right side surface of the outer side cylinder 7, airflow impinges on the radiator 12, heat on the radiator 12 is taken away after the airflow is heated by the radiator 12, and the airflow is discharged through the heat dissipation air outlet holes.

The specific embodiment IV is as follows: this embodiment is further defined in the first embodiment, and the air intake adjusting structure 8 includes a mounting ring 80, a connecting post 81, a slider 82, a chute 83, a connecting ring 84, a guide post 85, a connecting piece 86, a slot 87, an air vent 88, a wind shield 89, a wind shield 90, a connecting rod 91, and a stress post 92.

As shown in fig. 1-3: the air inlet adjusting structure 8 is arranged to adjust the air inlet of the cooling fan, and the air inlet of the air inlet adjusting structure 8 is in a maximum state in summer; in the eastern season, the air inlet of the air inlet adjusting structure 8 is in the lowest state, so that the condition that the temperature of the CPU14 is too low due to the fact that the air inlet of the air inlet adjusting structure 8 is too large in winter is avoided.

Fifth embodiment: the present embodiment is further limited by the fourth embodiment, the mounting ring 80 is welded to the air inlet barrel 6, four groups of sliding grooves 83 are uniformly formed in circumferential positions of the inner wall of the mounting ring 80, the sliding grooves 83 are matched with the sliding blocks 82 in size, and meanwhile the sliding blocks 82 are slidably arranged inside the sliding grooves 83.

As shown in fig. 3-5: the working mode of the air inlet adjusting structure 8 is as follows: the hand-held stress column 92 drives the connecting ring 84 through the connecting rod 91, so that the connecting ring 84 drives the connecting column 81 and the wind shield 89 to rotate, the wind shield 89 moves away from the air-permeable opening 88, and the air outlet quantity of the wind shield 90 is changed by changing the coverage area of the wind shield 89 to the air-permeable opening 88.

Specific embodiment six: in this embodiment, as a further limitation of the fifth embodiment, the cross sections of the sliding blocks 82 and the sliding grooves 83 are all in a dovetail shape, and the sliding blocks 82 are arranged in four groups and are uniformly mounted at the outer circumferential positions of the connecting rings 84, and four groups of connecting posts 81 are uniformly mounted at the inner circumferential positions of the connecting rings 84.

As shown in fig. 3-5: when the connecting ring 84 is stressed to rotate, the sliding block 82 on the connecting ring is arranged in the sliding groove 83 in a sliding manner, so that the connecting ring 84 in rotation can be limited and guided, and the stability of the connecting ring 84 in movement is ensured.

Seventh embodiment: in this embodiment, as a further limitation of the fourth embodiment, the wind shielding sheets 89 are uniformly arranged in four groups, and the ventilation openings 88 are uniformly arranged in four groups on the surface of the wind shielding plate 90, the ventilation openings 88 are blocked by the wind shielding sheets 89, and the ventilation openings 88 and the wind shielding sheets 89 are all fan-shaped.

As shown in fig. 3-4: the ventilation opening 88 is blocked by the wind shielding plate 89, and the air flow accelerated by the cooling fan enters the inside of the air outlet 10 through the ventilation opening 88 and impacts on the radiator 12 to complete the cooling work of the CPU 14.

Eighth embodiment: in this embodiment, the connecting piece 86 is a cross-shaped structure made of metal, and four sets of wind shields 89 are uniformly mounted on the outer side of the connecting piece 86, and the four sets of wind shields 89 are all rotating structures with the connecting piece 86 as the center of a circle.

As shown in fig. 3 and 8: four groups of wind shields 89 are uniformly arranged on the outer side of the connecting sheet 86, the four groups of wind shields 89 respectively shield or release the four groups of air inlets 88, and four groups of strip-shaped holes for limiting the connecting column 81 are uniformly formed in the circumferential position of the air inlet cylinder 6.

Detailed description nine: in this embodiment, as a further limitation of the seventh embodiment, four sets of mounting grooves are uniformly formed in the wind deflector 90, and guide posts 85 disposed in an arc shape are mounted in the four sets of mounting grooves, and the guide posts 85 are inserted into guide blocks at the bottom of the connecting post 81.

As shown in 3: the guide post 85 is inserted in the guide block at the bottom of the connecting post 81, and can limit and guide the windshield 89 during rotation, so that the stability of the windshield 89 during movement is ensured, friction force exists between the guide post 85 and the guide block, and friction force exists between the sliding block 82 and the sliding groove 83, so that the stability of the windshield 89 during static state can be ensured: positioning screws can be additionally arranged between the sliding blocks 82 and the sliding grooves 83, so that stability of the wind shielding piece 89 in a static state is further ensured.

Detailed description ten: in this embodiment, as a further limitation of the first embodiment, the heat sink 12 is fixed on the circuit board 13 by the mounting buckle 11, and the heat sink 12 includes the heat dissipation fins 16 and the fixing columns 17, the plurality of groups of heat dissipation fins 16 are uniformly installed at the circumferential positions of the outer sides of the fixing columns 17, and the cross section of the heat dissipation fins 16 is in an S-shaped arrangement.

As shown in fig. 6-7: a plurality of groups of radiating fins 16 are uniformly arranged at the peripheral positions of the outer sides of the fixed columns 17, the cross sections of the radiating fins 16 are arranged in an S shape, and the radiating fins 16 are made of 6063T5 aluminum alloy; the heat storage and conduction capacity of the heat sink can be increased by modifying the material of the heat sink; meanwhile, the wind speed of the fan can be increased or the high-speed area at the outlet of the fan can be fully utilized to increase the heat exchange coefficient of the radiator and reduce the thermal resistance; the heat dissipation effect of the heat sink can also be enhanced by increasing the number of heat dissipation fins and the heat dissipation area of the heat dissipation fins.

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)

1. A graphic processing apparatus for asymmetric graphic compression transmission, comprising:

the front cover (1), fix through the screw between figure processing apparatus casing (15) and front cover (1), and the surface mounting of front cover (1) has stationary blade (3), install dust separation net (5) on stationary blade (3) simultaneously, front cover (1) surface mounting has the display screen, and display screen and air quantity sensor (9) electric connection on front cover (1), the inside spiro union of figure processing apparatus casing (15) has outside barrel (7), and the inside and air inlet section of thick bamboo (6) fixed connection of outside barrel (7), the inside of air inlet section of thick bamboo (6) is fixed and is provided with air quantity sensor (9) in the inside right side of air inlet section of thick bamboo (6), the inside left side of air inlet section of thick bamboo (6) is fixed and is provided with radiator fan, the inner side of collar (80) on air inlet regulation structure (8) is provided with go-between (84), and the inner side of go-between (84) is installed deep bead (90), set up ventilation opening (88) simultaneously, and ventilation opening (88) is carried out through wind shielding piece (89); the outer side of the front cover (1) is provided with a limit groove, a limit strip (4) is inserted into the limit groove, the limit strip (4) is welded on the right side surface of the fixing piece (3), and the surface of the front cover (1) is provided with two groups of stress grooves (2);

the inner side wall of the image processing device shell (15) is in threaded connection with a circuit main board (13), a CPU (14) is embedded on the circuit main board (13), and meanwhile, the CPU (14) is in contact with the radiator (12) through silicone grease;

the cross sections of the air inlet cylinder (6) and the outer cylinder (7) are of concentric circle structures, the combined cross sections of the air inlet cylinder (6) and the outer cylinder (7) are arranged in a concave shape, and meanwhile, the right side of the inside of the outer cylinder (7) is provided with an air outlet (10), and the air outlet (10) is arranged opposite to the radiator (12);

eight groups of heat dissipation air outlet holes are uniformly formed in the circumferential position of the right side surface of the outer cylinder body (7), heat dissipation holes are formed in the shell (15) of the image processing device, and the heat radiator (12) is arranged opposite to the heat dissipation air outlet holes;

the air inlet adjusting structure (8) comprises a mounting ring (80), a connecting column (81), a sliding block (82), a sliding chute (83), a connecting ring (84), a guide column (85), a connecting sheet (86), a slot (87), an air ventilation opening (88), a wind shielding plate (89), a wind shielding plate (90), a connecting rod (91) and a stress column (92);

the mounting ring (80) is welded with the air inlet cylinder (6), four groups of sliding grooves (83) are uniformly formed in the circumferential position of the inner wall of the mounting ring (80), the sliding grooves (83) are matched with the sliding blocks (82) in size, and meanwhile the sliding blocks (82) are arranged in the sliding grooves (83) in a sliding mode;

the sections of the sliding blocks (82) and the sliding grooves (83) are all in a dovetail shape, the sliding blocks (82) are arranged in four groups and are uniformly arranged at the outer circumferential positions of the connecting rings (84), and four groups of connecting columns (81) are uniformly arranged at the circumferential positions of the inner walls of the connecting rings (84);

the wind shields (89) are uniformly arranged into four groups, the air ventilation openings (88) are uniformly arranged on the surface of the wind shields (90), the air ventilation openings (88) are blocked by the wind shields (89), and the air ventilation openings (88) and the wind shields (89) are all fan-shaped;

the connecting piece (86) is of a cross-shaped structure made of metal materials, four groups of wind shields (89) are uniformly arranged on the outer side of the connecting piece (86), and the four groups of wind shields (89) are all of a rotating structure taking the connecting piece (86) as a circle center;

four groups of mounting grooves are uniformly formed in the wind shield (90), guide posts (85) which are arranged in an arc shape are arranged in the four groups of mounting grooves, and the guide posts (85) are inserted into guide blocks at the bottom of the connecting post (81);

the radiator (12) is fixed on the circuit main board (13) through the mounting buckle (11), the radiator (12) comprises radiating fins (16) and fixing columns (17), a plurality of groups of radiating fins (16) are uniformly arranged at the circumferential positions of the outer sides of the fixing columns (17), and the cross sections of the radiating fins (16) are in S-shaped arrangement.

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