CN215895373U - Platform architecture based on big data of computer - Google Patents

Abstract

The utility model belongs to the technical field of big data servers, in particular to a platform framework based on computer big data, aiming at the problems of poor heat dissipation effect and poor buffering and damping effect of a big data server in a working state, the utility model provides the following scheme, which comprises a placing box and two box doors which are rotationally connected with the placing box, wherein a server main body is arranged in the placing box; according to the utility model, the supporting block and the positioning rod form effective support for the server main body and buffer treatment for the server main body, the server main body and the bottom of the placing box are suspended, so that the natural cooling effect of the server main body through the heat dissipation channel is effectively improved, meanwhile, the condensing pipe is arranged at the bottom of the server main body and is used for improving the space environment temperature at the bottom of the server main body in the placing box, and the cooling fan at the top of the placing box is matched for carrying out air cooling heat dissipation on the top of the server main body, so that the cooling and heat dissipation effects of the server main body during working are effectively improved.

Description

Platform architecture based on big data of computer

Technical Field

The utility model relates to the technical field of big data servers, in particular to a platform architecture based on computer big data.

Background

Since the server needs to respond to and process a service request, the server generally has the capability of undertaking and guaranteeing the service, and big data refers to a data set which cannot be captured, managed and processed by a conventional software tool within a certain time range, and is a massive, high-growth-rate and diversified information asset which needs a new processing mode to have stronger decision-making power, insight discovery power and flow optimization capability.

The big data processor comprises a USB control card, an acquisition storage card, a power supply card and a display reset card; the temperature rise of big data server can lead to the power supply to go wrong, for example supply voltage is unstable, burns out electrical components easily, takes place phenomena such as power explosion even, and consequently big data server is good then especially important at its thermal diffusivity of during operation to big data server is at the during operation, easily produces vibrations, and parts that appear leading to because of rocking are loose easily.

Therefore, a platform architecture based on computer big data is needed to solve the problems of poor heat dissipation effect and poor buffering and shock absorption effect of a big data server in a working state.

SUMMERY OF THE UTILITY MODEL

The platform architecture based on the big data of the computer solves the problems of poor heat dissipation effect and poor buffering and shock absorption effect of a big data server in a working state.

In order to achieve the purpose, the utility model adopts the following technical scheme: the platform architecture based on the big data of the computer comprises a placing box and two box doors which are rotatably connected with the placing box, wherein a server main body is arranged inside the placing box, and the placing box further comprises

The four placing blocks are all positioned inside the placing box, a buffer spring is fixed between the placing blocks and the inner wall of the bottom of the placing box, and stop blocks are fixed at the outer ends of the two placing blocks far away from the box door;

the cooling device comprises a cooling fan, wherein the cooling fan is installed on the inner wall of the top of the placing box, the cooling box is installed at the bottom of the placing box, a condensing pipe communicated with the cooling box is arranged below the server main body, and a buffering assembly matched with the placing block is installed inside the placing box.

Preferably, the buffer assembly comprises

The four rotating gears are rotatably mounted on the inner wall of the bottom of the placing box, a pressing rack is fixed on the side wall of one side of each placing block, the pressing rack is meshed with one side of the adjacent rotating gear, a lifting rack is meshed with the other side of the rotating gear, and the lifting racks all penetrate through the inner wall of the top of the cooling box in a sliding mode;

the lifting plate is connected with the inner wall of the cooling box in a sliding mode, the bottom ends of the four lifting racks are fixed to the top face of the lifting plate, and circulation grooves are formed in the side walls of the two sides of the cooling box.

Preferably, one end of the condensing pipe is located at the center of the upper part of the jacking plate, a flow guide sleeve communicated with the condensing pipe is arranged above the jacking plate, and the other end of the condensing pipe is located below the jacking plate.

Preferably, the condenser pipe is distributed in an S shape in an up-down staggered manner, and the side walls of the placing box, which are positioned at two sides of the condenser pipe, are provided with heat dissipation channels.

Preferably, the inner wall of the bottom of the placing box is fixed with a plurality of positioning sleeves which are uniformly distributed, the inner walls of the positioning sleeves are connected with positioning rods in a sliding mode, and positioning springs are fixed between the positioning rods and the inner wall of the bottom of the placing box.

Preferably, the vertical cross sections of the stop blocks are distributed in an L shape, and the top surfaces of the positioning rods and the upper surfaces of the stop blocks are located on the same horizontal plane.

Compared with the prior art, the utility model has the beneficial effects that:

1. in the utility model, the four supporting blocks and the plurality of positioning rods are used for supporting and placing the bottom of the server main body, the effective support for the server main body and the buffer treatment are formed by the elastic force action of the buffer spring and the positioning spring, the server main body and the bottom of the placing box are suspended, thereby forming a certain space interval, effectively improving the effect of natural cooling through the heat dissipation channel, meanwhile, the bottom of the server main body is provided with a condenser pipe for improving the space environment temperature at the bottom of the server main body in the placing box, water cooling the server body to a certain degree, and performing air cooling heat dissipation on the top of the server body by matching with a heat dissipation fan arranged on the top of the box, therefore, the cooling and radiating effect of the server main body during working is effectively improved, and the working effect of components inside the server main body is improved.

2. When the server main body moves downwards due to vibration, the positioning rod and the pressing rack can be driven to synchronously move downwards, the vibration sense of the server main body is effectively reduced, the stability of the server main body in the placing box is ensured, and the four lifting racks drive the jacking plates to upwards pull in the cooling box, so that condensed water in the cooling box quickly passes through the condenser pipe, the flowing speed of the cooled water in the condenser pipe is improved, and the cooling effect of the condenser pipe on the bottom of the server in the placing box is further improved.

Drawings

FIG. 1 is a schematic diagram of an overall structure of a platform architecture based on big data of a computer according to the present invention;

FIG. 2 is a partial structural diagram of a buffer component of a platform architecture based on big data of a computer according to the present invention;

FIG. 3 is a schematic diagram of a partial structure at a flow-through slot of a platform architecture based on big data of a computer according to the present invention;

FIG. 4 is a schematic diagram of a local structure at a server body of a platform architecture based on big data of a computer according to the present invention;

fig. 5 is a schematic diagram of a partial structure at a condenser tube of a platform architecture based on big data of a computer according to the present invention.

In the figure: 1. placing a box; 2. a box door; 3. a server main body; 4. placing the blocks; 5. a buffer spring; 6. a stopper; 7. a heat radiation fan; 8. a cooling tank; 9. a condenser tube; 10. a buffer assembly; 101. a rotating gear; 102. pressing the rack; 103. lifting the rack; 104. a jacking plate; 105. a circulation tank; 11. a pod; 12. a heat dissipation channel; 13. a positioning sleeve; 14. positioning a rod; 15. and positioning the spring.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Referring to fig. 1-5, a platform architecture based on computer big data comprises a placing box 1 and two box doors 2 rotatably connected with the placing box 1, wherein a server main body 3 is arranged inside the placing box 1, the placing box 1 further comprises four placing blocks 4, the four placing blocks 4 are all positioned inside the placing box 1, a buffer spring 5 is fixed between the placing blocks 4 and the inner wall of the bottom of the placing box 1, and stop blocks 6 are fixed at the outer ends of the two placing blocks 4 far away from the box doors 2; the cooling device comprises a cooling fan 7, the cooling fan 7 is arranged on the inner wall of the top of the placing box 1, a cooling box 8 is arranged at the bottom of the placing box 1, a condenser pipe 9 communicated with the cooling box 8 is arranged below the server main body 3, a buffer assembly 10 matched with the placing block 4 is arranged inside the placing box 1, specifically, the server main body 3 is placed in a suspended placing state in the placing box 1 through the effects of the placing block 4 and a stop block 6, so that the natural cooling effect of the server main body is improved, the bottom of the server main body 3 is subjected to space cooling treatment through the arrangement of the condenser pipe 9, and top air cooling heat dissipation is carried out on the server main body 3 through the cooling fan 7, so that the heat dissipation effect of the server main body 3 in use is effectively improved, the service life of internal components is effectively prolonged, the arrangement of the buffer assembly 10 can be matched with the elastic action of the buffer spring 5, the buffering and damping effect on the server main body 3 is improved, and the heat dissipation and cooling effects on the server main body 3 can be further improved.

The buffer assembly 10 comprises four rotating gears 101, the four rotating gears 101 are rotatably mounted on the inner wall of the bottom of the placing box 1, a pressing rack 102 is fixed on the side wall of one side of each placing block 4, the pressing rack 102 is meshed with one side of the adjacent rotating gear 101, a lifting rack 103 is meshed with the other side of the rotating gear 101, and the lifting racks 103 all penetrate through the inner wall of the top of the cooling box 8 in a sliding manner; the lifting plate 104 is slidably connected with the inner wall of the cooling box 8, the bottom ends of the four lifting racks 103 are fixed to the top surface of the lifting plate 104, circulation grooves 105 are formed in the side walls of the two sides of the cooling box 8, specifically, sufficient cooling water is placed in the cooling box 8, so that when the lifting plate is lifted upwards, the cooling water on the lifting plate 104 can be compressed to circulate from the condensation pipe 9, the circulation grooves 105 are arranged, the cooling water flowing back from the condensation pipe 9 can reach the bottom of the cooling box 8 conveniently, and the cooling water is cooled by the cooling box 8 and then is supplemented to the upper side of the lifting plate 104; when the server main body 3 receives vibration, the pressing rack 102 is driven to move downwards through the elastic force of the buffer spring 5, and when the pressing rack 102 moves downwards, the rotating gear 101 rotates through the meshing transmission between the pressing rack 102 and the rotating gear 101, and due to the meshing transmission between the lifting racks 103 and the rotating gear 101, the four lifting racks 103 drive the lifting plate 104 to be pulled upwards in the cooling box 8, so that condensed water in the cooling box 8 quickly passes through the condensing pipe 9.

The one end of condenser pipe 9 is located the top center department of jacking board 104, and the top of jacking board 104 is provided with the kuppe 11 with condenser pipe 9 intercommunication, and the other end of condenser pipe 9 is located the below of jacking board 104, and is concrete, the setting of kuppe 11 for jacking board 104 carries out the circulation in the better entering condenser pipe 9 and handles when last step-up contracts the cooling water at its top, thereby effectively improves its effect when the condensation cools down.

Condenser pipe 9 is upper and lower staggered form S-shaped and distributes, places case 1 and all has seted up heat dissipation channel 12 at the both sides lateral wall that is located condenser pipe 9, and is concrete, and the setting of condenser pipe 9 shape improves the temperature to 3 bottom spaces of server main part to the improvement is to server main part 3 at the radiating effect of during operation bottom.

Place the bottom inner wall of case 1 and be fixed with a plurality of position sleeve 13 that are evenly distributed, the inner wall sliding connection of position sleeve 13 has locating lever 14, locating lever 14 and place all be fixed with positioning spring 15 between the bottom inner wall of case 1, it is concrete, locating lever 14 and positioning spring 15's setting, both can strengthen the supporting effect to the bottom of server main part 3, thereby improve the stability of server main part 3 when unsettled placing, can cooperate buffer spring 5's spring action again, further improve the buffering shock attenuation effect of server main part 3 when the during operation receives vibrations.

The vertical section of dog 6 is L shape and distributes, and the top surface of locating lever 14 and the upper surface of dog 6 are located same horizontal plane, and is concrete, and the area of contact of its bottom surface and the side with server main part 3 is increased in the setting of dog 6 shape to the top surface of cooperation locating lever 14 supports server main part 3's bottom surface, thereby effectively improves server main part 3 and places the unsettled stability of placing in the case 1.

The working principle is as follows: when the server main body 3 is used, the bottom of the server main body 3 is supported and placed through the four supporting blocks and the positioning rods 14, the server main body 3 is effectively supported and buffered through the elastic action of the buffer springs 5 and the positioning springs 15, the server main body 3 and the bottom of the placing box 1 are suspended to form a certain space interval, the natural cooling effect of the server main body 3 through the heat dissipation channel 12 is effectively improved, meanwhile, the condensing pipe 9 is arranged at the bottom of the server main body 3 and used for improving the space environment temperature at the bottom of the server main body 3 in the placing box 1 and carrying out water cooling to a certain degree, and the heat dissipation fan 7 at the top of the placing box 1 is matched for carrying out air cooling heat dissipation at the top of the server main body 3, so that the cooling heat dissipation effect of the server main body 3 during working is effectively improved, thereby improving the working effect of the components inside the server main body 3; when the server main body 3 is subjected to external vibration or small-amplitude vibration occurs when it is operated, at the moment, the positioning rod 14 and the pressing rack 102 are driven to synchronously move downwards by the elastic force of the buffer spring 5 and the positioning spring 15, the vibration feeling of the server main body 3 is effectively reduced, the stability of the server main body 3 in the placing box 1 is ensured, and the pressing rack 102, when moving downward, through its meshing transmission with the rotating gear 101, makes the rotating gear 101 rotate, because the lifting racks 103 are in meshing transmission with the rotating gear 101, the four lifting racks 103 drive the lifting plate 104 to be drawn upwards in the cooling box 8, therefore, the condensed water in the cooling box 8 quickly passes through the condensation pipe 9, the flowing speed of the cooling water in the condensation pipe 9 is improved, and the cooling effect of the cooling water on the bottom of the server in the placing box 1 by the condensation pipe 9 is further improved.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and equivalent alternatives or modifications according to the technical solution of the present invention and the inventive concept thereof should be covered by the scope of the present invention.

Claims (6)

1. The platform architecture based on the big data of the computer comprises a placing box (1) and two box doors (2) rotatably connected with the placing box (1), wherein a server main body (3) is arranged inside the placing box (1), and the platform architecture is characterized in that the placing box (1) further comprises

The refrigerator door comprises a box door body (2), and is characterized by comprising four placing blocks (4), wherein the four placing blocks (4) are all positioned inside a placing box (1), a buffer spring (5) is fixed between each placing block (4) and the inner wall of the bottom of the placing box (1), and a stop block (6) is fixed at the outer ends of the two placing blocks (4) far away from the box door (2);

radiator fan (7), radiator fan (7) install in place the top inner wall of case (1), place the bottom of case (1) and install cooler bin (8), the below of server main part (3) is provided with condenser pipe (9) with cooler bin (8) intercommunication, the internally mounted of placing case (1) has and places piece (4) matched with buffering subassembly (10).

2. The computer big data based platform architecture according to claim 1, wherein the buffer component (10) comprises

The cooling box comprises four rotating gears (101), the four rotating gears (101) are rotatably mounted on the inner wall of the bottom of the placing box (1), a pressing rack (102) is fixed on the side wall of one side of each placing block (4), the pressing rack (102) is meshed with one side of the adjacent rotating gear (101), a lifting rack (103) is meshed with the other side of each rotating gear (101), and each lifting rack (103) penetrates through the inner wall of the top of the cooling box (8) in a sliding mode;

the lifting plate (104) is connected with the inner wall of the cooling box (8) in a sliding mode, the bottom ends of the four lifting racks (103) are fixed to the top face of the lifting plate (104), and circulation grooves (105) are formed in the side walls of the two sides of the cooling box (8).

3. The computer big data-based platform architecture according to claim 2, wherein one end of the condenser pipe (9) is located at the center above the lifting plate (104), a diversion cover (11) communicated with the condenser pipe (9) is arranged above the lifting plate (104), and the other end of the condenser pipe (9) is located below the lifting plate (104).

4. The platform architecture based on the big data of the computer according to claim 1, wherein the condenser tubes (9) are distributed in an S shape with an up-down staggered manner, and the side walls of the placing box (1) at both sides of the condenser tubes (9) are provided with heat dissipation channels (12).

5. The computer big data based platform architecture according to claim 1, characterized in that a plurality of positioning sleeves (13) are fixed on the inner wall of the bottom of the placing box (1) and are evenly distributed, a positioning rod (14) is connected to the inner wall of the positioning sleeve (13) in a sliding manner, and a positioning spring (15) is fixed between the positioning rod (14) and the inner wall of the bottom of the placing box (1).

6. The computer big data based platform architecture according to claim 5, wherein the vertical cross-section of the block (6) is distributed in an L shape, and the top surface of the positioning rod (14) and the upper surface of the block (6) are located at the same horizontal plane.

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