CN113220088B

CN113220088B - GPU server with high operation and maintenance efficiency

Info

Publication number: CN113220088B
Application number: CN202110562105.6A
Authority: CN
Inventors: 郭伟城; 龙剑
Original assignee: Shenzhen Haleiyun Information Technology Co ltd
Current assignee: Shenzhen Haleiyun Information Technology Co ltd
Priority date: 2021-05-24
Filing date: 2021-05-24
Publication date: 2022-11-25
Anticipated expiration: 2041-05-24
Also published as: CN113220088A

Abstract

The invention discloses a GPU server with high operation and maintenance efficiency, which comprises a box body, a motor, a rotating mechanism, a reciprocating mechanism, a pushing mechanism, a ventilating mechanism, a knocking mechanism and a dust removing mechanism, wherein the motor is fixedly welded on the top wall of the box body, the rotating mechanism is fixedly welded at the output end of the motor, the pushing mechanism is fixedly welded on the side wall of the box body, the reciprocating mechanism which drives the pushing mechanism to move in a reciprocating mode is fixedly welded on the inner wall of the box body, and the ventilating mechanism which enables air inside the box body to circulate is arranged on the side wall of the box body. According to the invention, through the arrangement of the structures such as the negative pressure fan, the rotating shaft and the air outlet, the negative pressure fan extracts hot air in the box body from the air outlet to form a herringbone air path from bottom to top, so that the heat dissipation efficiency is accelerated, the push rod extrudes cooling liquid in the cooling box from the liquid outlet joint to the circulating pipe through the piston for circulation, the circulating pipe is embedded in the inner wall of the box body, so that high temperature generated in the box body is further cooled, and the heat dissipation performance is obviously improved.

Description

GPU server with high operation and maintenance efficiency

Technical Field

The invention relates to the technical field of GPU servers, in particular to a GPU server with high operation and maintenance efficiency.

Background

The GPU server is a computer and corollary equipment thereof used in the technical field of computer science, and is mainly applied to 3D visualization of geospatial data, application research and education such as video image stabilization, filtering, mosaic, transcoding and the like, such as imaging and processing, structural analysis, astronomical physics such as computational physics and the like, computational streaming media dynamics, animation production, meteorological forecasting such as high-performance computation and the like, and industrial users such as quantum physics, biochemistry, design, geological exploration and the like.

Current GPU server often only dispels the heat through the radiator that equipment was taken certainly, and the city in south often the temperature is higher when summer, and when the GPU server was placed and is used in the open air, including the inside heat dissipation of GPU server, often can be because of the unable timely exhaust problem of the inside heat of GPU server for unstable condition appears in the operation of GPU server, seriously influences the normal work of GPU server.

Disclosure of Invention

The invention aims to solve the defects in the prior art and provides a GPU server with high operation and maintenance efficiency.

In order to achieve the purpose, the invention adopts the following technical scheme:

the utility model provides an fortune dimension efficient GPU server, includes box, motor, slewing mechanism, reciprocating mechanism, pushes away crowded mechanism, ventilation mechanism, knocking mechanism and dust removal mechanism, the roof welded fastening of box has the motor, the output welded fastening of motor has slewing mechanism, box lateral wall welded fastening has the pushing mechanism, box inner wall welded fastening has the drive to push away the reciprocating mechanism of mechanism motion, the ventilation mechanism who makes the inside gas circulation of box is seted up to the box lateral wall, the top inner wall symmetry of box rotates and is connected with the knocking mechanism who collides the shake to ventilation mechanism, the last welded fastening of slewing mechanism has the dust removal mechanism who carries out electrostatic absorption to the dust in the box.

Preferably, slewing mechanism includes pivot, sector gear and negative pressure fan, the output welded fastening of motor has the pivot, the pivot is kept away from the one end of motor and is run through the bottom inner wall of box roof back rotation connection at the box, pivot top lateral wall welded fastening has the negative pressure fan, the bottom welded fastening of pivot has sector gear.

Preferably, reciprocating mechanism includes base, spout, rectangle frame and rack, base welded fastening is at the box inner wall, the spout has been seted up along the horizontal direction to the inner wall of base, sliding connection has the rectangle frame in the spout, the inside wall symmetry welded fastening of rectangle frame has the rack, rack and sector gear meshing are connected.

Preferably, push mechanism includes push rod, piston, cooler bin, goes out liquid joint, liquid feed connector and circulating pipe, the lateral wall welded fastening of box has the cooler bin, the lateral wall welded fastening of rectangle frame has the push rod, the one end that the rectangle frame was kept away from to the push rod runs through box and cooler bin inner wall after welded fastening in proper order and has the piston, the sealed sliding connection of piston is in the cooler bin, the inner wall of cooler bin one end has been seted up out liquid joint and liquid feed connector, the box inner wall inlays and is equipped with the circulating pipe, the both ends of circulating pipe respectively with go out liquid joint, the fixed intercommunication of liquid feed connector.

Preferably, the ventilation mechanism comprises through holes, a filter screen frame, sliding blocks, grooves, springs and air outlet holes, the through holes are symmetrically formed in the side wall of the box body, the grooves are symmetrically formed in the inner wall of each through hole, and each groove is internally and elastically connected with a sliding block through a spring.

Preferably, every equal sliding connection of slider is in a recess that corresponds, two the common welded fastening of slider has the filter screen frame, the exhaust vent has been seted up to the roof symmetry of box, the welded fastening has the filter screen in the exhaust vent.

Preferably, knocking mechanism includes action wheel, conveyer belt, follows driving wheel, bull stick, fixed block and cam, action wheel welded fastening is in the pivot, box top inner wall symmetry rotates and is connected with the bull stick, box inner wall symmetry welded fastening has the fixed block, the bottom of bull stick is rotated and is connected at the fixed block top, every equal welded fastening has from the driving wheel on the bull stick, two from the driving wheel through two dislocation set's conveyer belt respectively with the action wheel connection, the lateral wall welded fastening of bull stick has the cam.

Preferably, the dust removal mechanism comprises a friction brush and a rubber plate, the friction brush is made of fur materials, the friction brush is symmetrically and fixedly connected to the side wall of the rotating shaft, and the rubber plate is symmetrically welded and fixed to the inner wall of the box body.

The invention has the following beneficial effects:

1. through the arrangement of the structures such as the negative pressure fan, the rotating shaft, the air outlet and the like, the motor drives the rotating shaft to rotate, the rotating shaft drives the negative pressure fan and the sector gear to rotate, hot air in the box body is extracted from the air outlet after the negative pressure fan rotates, cold air enters from through holes in two sides of the box body, a herringbone air path is formed from bottom to top, the heat dissipation efficiency is accelerated, and a filter screen arranged in the air outlet prevents external foreign matters from entering the box body from the air outlet, so that the normal work of the GPU component is influenced;

2. by arranging the structures of the sector gear, the rack, the rectangular frame and the like, in the process that the sector gear rotates along with the rotating shaft, the sector gear is firstly meshed with one rack on the inner side wall of the rectangular frame to drive the rectangular frame to slide towards the right side in the sliding chute, then, a tooth socket at one end of the sector gear is meshed with the other rack on the inner side wall of the rectangular frame, then, the sector gear drives the rectangular frame to slide towards the left side, and the process is repeated to enable the rectangular frame to reciprocate in the sliding chute;

3. by arranging the piston, the cooling box, the push rod and other structures, when the push rod slides to the left side along with the rectangular frame, the push rod extrudes cooling liquid in the cooling box from the liquid outlet joint to the circulating pipe through the piston to circulate, the circulating pipe is embedded in the inner wall of the box body to further cool high temperature generated in the box body, and the heat dissipation performance is obviously improved;

4. through the arrangement of the structures such as the driving wheel, the driven wheels and the cam, the driving wheel synchronously rotates along with the rotating shaft, so that the driving wheel drives the two driven wheels to rotate through the two conveying belts arranged in a staggered mode, the two driven wheels drive the corresponding rotating rods to rotate, and the rotating rods drive the cam to periodically impact the filter screen frame, so that the filter screen frame vibrates leftwards and rightwards in the groove, dust and foreign matters on the filter screen frame are shaken off, the situation that the dust and the foreign matters block filter screen holes in the filter screen frame is avoided, and the heat dissipation efficiency in the box body is influenced;

5. through setting up dust removal mechanism, the pivot drives the periodic and rubber slab friction of friction brush, and when rubber slab and friction brush looks mutual friction, the unnecessary positive charge of negative charge of rubber slab is shown as the burden, and the unnecessary negative charge of friction brush positive charge is shown as the positive, carries out electrostatic absorption to the dust that enters into in the box, avoids the dust accumulation to produce troubles such as short circuit on GPU component.

Drawings

Fig. 1 is a schematic structural diagram of a GPU server with high operation and maintenance efficiency according to the present invention;

FIG. 2 is a schematic view of the structure of FIG. 1 taken in a vertical direction;

FIG. 3 is a perspective view of the rectangular frame and rack portion of FIG. 2;

fig. 4 is an enlarged schematic view of the structure at a in fig. 2.

In the figure: 1 box body, 2 motors, 3 rotating mechanisms, 301 rotating shafts, 302 sector gears, 303 negative pressure fans, 4 reciprocating mechanisms, 401 bases, 402 chutes, 403 rectangular frames, 404 racks, 5 pushing mechanisms, 501 push rods, 502 pistons, 503 cooling boxes, 504 liquid outlet connectors, 505 liquid inlet connectors, 506 circulating pipes, 6 ventilation mechanisms, 601 through holes, 602 filter screen frames, 603 sliders, 604 grooves, 605 springs, 606 air outlet holes, 7 knocking mechanisms, 701 driving wheels, 702 conveying belts, 703 driven wheels, 704 rotating rods, 705 fixed blocks, 8 dust removing mechanisms, 801 friction brushes and 802 rubber plates.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. This invention may, however, be embodied in many different forms than those specifically described herein, and it will be apparent to those skilled in the art that many more modifications are possible without departing from the spirit and scope of the invention.

Referring to fig. 1-4, a high-efficiency GPU server for operation and maintenance comprises a box body 1, a motor 2, a rotating mechanism 3, a reciprocating mechanism 4, a pushing mechanism 5, a ventilation mechanism 6, a knocking mechanism 7 and a dust removal mechanism 8, wherein the motor 2 is welded and fixed on the top wall of the box body 1, the rotating mechanism 3 is welded and fixed on the output end of the motor 2, the pushing mechanism 5 is welded and fixed on the side wall of the box body 1, the reciprocating mechanism 4 for driving the pushing mechanism 5 to move is welded and fixed on the inner wall of the box body 1, the ventilation mechanism 6 for circulating gas inside the box body 1 is arranged on the side wall of the box body 1, the knocking mechanism 7 for performing collision and shaking on the ventilation mechanism 6 is symmetrically and rotatably connected to the inner wall of the top of the box body 1, and the dust removal mechanism 8 for performing electrostatic adsorption on dust in the box body 1 is welded and fixed on the rotating mechanism 3.

Slewing mechanism 3 includes pivot 301, sector gear 302 and negative pressure fan 303, motor 2's output welded fastening has pivot 301, the one end that motor 2 was kept away from to pivot 301 runs through behind the box 1 roof and rotates the bottom inner wall of connection at box 1, pivot 301 top lateral wall welded fastening has negative pressure fan 303, the bottom welded fastening of pivot 301 has sector gear 302, motor 2's output drives pivot 301 and rotates, thereby pivot 301 drives negative pressure fan 303 and sector gear 302 rotates, negative pressure fan 303 takes the steam in the box 1 out from exhaust vent 606 after rotating.

The reciprocating mechanism 4 comprises a base 401, a sliding groove 402, a rectangular frame 403 and a rack 404, the base 401 is welded and fixed on the inner wall of the box body 1, the sliding groove 402 is formed in the inner wall of the base 401 along the horizontal direction, the rectangular frame 403 is connected in the sliding groove 402 in a sliding mode, the rack 404 is symmetrically welded and fixed on the inner side wall of the rectangular frame 403, the rack 404 is meshed and connected with the sector gear 302, the sector gear 302 is firstly meshed with one rack 404 on the inner side wall of the rectangular frame 403 in the rotating process along with the rotating shaft 301, the rectangular frame 403 is driven to slide towards the right side in the sliding groove 402, then, a tooth space at one end of the sector gear 302 is meshed with the other rack 404 on the inner side wall of the rectangular frame 403, the sector gear 302 is about to be separated from the previous rack 404, then, the sector gear 302 drives the rectangular frame 403 to slide towards the left side, and the process is repeated, so that the rectangular frame 403 reciprocates in the sliding groove 402.

The pushing mechanism 5 comprises a push rod 501, a piston 502, a cooling tank 503, a liquid outlet joint 504, a liquid inlet joint 505 and a circulating pipe 506, wherein the cooling tank 503 is welded and fixed on the side wall of the tank body 1, the push rod 501 is welded and fixed on the side wall of the rectangular frame 403, the piston 502 is welded and fixed on one end of the push rod 501, which is far away from the rectangular frame 403, after sequentially penetrating through the inner walls of the tank body 1 and the cooling tank 503, the piston 502 is hermetically and slidably connected into the cooling tank 503, the liquid outlet joint 504 and the liquid inlet joint 505 are arranged on the inner wall of one end of the cooling tank 503, the circulating pipe 506 is embedded in the inner wall of the tank body 1, two ends of the circulating pipe 506 are respectively and fixedly communicated with the liquid outlet joint 504 and the liquid inlet joint 505, the rectangular frame 403 drives the push rod 501 to synchronously move in the reciprocating sliding process of the rectangular frame 403 in the sliding groove 402, so that when the push rod 501 slides to the left, cooling liquid is filled in the cooling tank 503, the cooling liquid is extruded by the push rod 501 from the liquid outlet joint 504 to the circulating pipe from the cooling tank 504 to the circulating pipe 505, and when the piston 502 moves to the circulating pipe 505, the cooling tank 505, the circulating pipe is pumped into the cooling tank 503, and only one-way valve is arranged in the cooling tank 506.

The ventilation mechanism 6 comprises a through hole 601, a filter screen frame 602, a sliding block 603, grooves 604, springs 605 and air outlets 606, the through hole 601 is symmetrically formed in the side wall of the box body 1, the grooves 604 are symmetrically formed in the inner wall of the through hole 601, each groove 604 is internally and elastically connected with a sliding block 603 through the spring 605, the sliding blocks 603 drive the filter screen frame 602 to slide left and right in the grooves 604, the sliding blocks 603 drive the filter screen frame 602 to shake continuously under the elastic action of the springs 605, dust and foreign matters on the filter screen frame 602 are shaken off, and the filter screen holes in the filter screen frame 602 are prevented from being blocked by the dust and the foreign matters, so that the heat dissipation efficiency in the box body 1 is influenced.

Every equal sliding connection of slider 603 is in a recess 604 that corresponds, and two common welded fastening of slider 603 have a filter screen frame 602, and exhaust vent 606 has been seted up to the roof symmetry of box 1, and the welded fastening has the filter screen in the exhaust vent 606, and the filter screen that sets up in the exhaust vent 606 avoids external foreign matter to enter into inside the box 1 from the exhaust vent 606 to influence the normal work of GPU subassembly.

The knocking mechanism 7 comprises a driving wheel 701, transmission belts 702, driven wheels 703, rotating rods 704, fixed blocks 705 and cams 706, the driving wheel 701 is welded and fixed on the rotating shaft 301, the rotating rods 704 are symmetrically and rotatably connected to the inner wall of the top of the box body 1, the fixed blocks 705 are symmetrically and fixedly welded to the inner wall of the box body 1, the bottom ends of the rotating rods 704 are rotatably connected to the tops of the fixed blocks 705, the driven wheels 703 are welded and fixedly connected to each rotating rod 704, the two driven wheels 703 are respectively connected with the driving wheel 701 through the two staggered transmission belts 702, the cams 706 are welded and fixedly connected to the side walls of the rotating rods 704, the driving wheel 701 synchronously rotates along with the rotating shaft 301, so that the driving wheel 701 drives the two driven wheels 703 to rotate through the two staggered transmission belts 702, the two driven wheels 703 drive the corresponding rotating rods 704 to rotate, and the rotating rods 704 drive the cams 706 to periodically impact the filter screen frame 602, so that the filter screen frame 602 vibrates left and right, and dust and foreign matters on the filter screen frame 602 are shaken off.

The dust removing mechanism 8 comprises a friction brush 801 and a rubber plate 802, wherein the friction brush 801 is made of fur materials, the friction brush 801 is symmetrically and fixedly connected to the side wall of the rotating shaft 301, the rubber plate 802 is symmetrically welded and fixed on the inner wall of the box body 1, each object carries positive and negative charges, static electricity is generated when the positive and negative charges of a certain object are redundant and positive, the rotating shaft 301 drives the friction brush 801 to periodically rub against the rubber plate 802, when the rubber plate 802 and the friction brush 801 rub against each other, the redundant positive charges of the negative charges of the rubber plate 802 are negative, the redundant negative charges of the positive charges of the friction brush 801 are positive, dust entering the box body 1 is subjected to electrostatic adsorption, and faults such as short circuit and the like caused by dust accumulation on a GPU element are avoided.

In the invention, a user firstly turns on the motor 2, so that the motor 2 drives the rotating shaft 301 to rotate, the rotating shaft 301 drives the negative pressure fan 303 and the sector gear 302 to rotate, hot air in the box body 1 is extracted from the air outlet 606 by the negative pressure fan 303 after the negative pressure fan 303 rotates, cold air enters from through holes on two sides of the box body 1 to form a herringbone air path from bottom to top, the heat dissipation efficiency is accelerated, and a filter screen arranged in the air outlet 606 prevents external foreign matters from entering the box body 1 from the air outlet 606, so that the normal operation of the GPU component is influenced.

In the process that the sector gear 302 rotates along with the rotating shaft 301, firstly, the sector gear 302 is meshed with one rack 404 on the inner side wall of the rectangular frame 403, so that the rectangular frame 403 is driven to slide towards the right side in the sliding groove 402, then, one end tooth socket of the sector gear 302 is meshed with the other rack 404 on the inner side wall of the rectangular frame 403, the sector gear 302 is about to be separated from the previous rack 404, then, the sector gear 302 drives the rectangular frame 403 to slide towards the left side, and then, the process is repeated, so that the rectangular frame 403 reciprocates in the sliding groove 402.

In the process that the rectangular frame 403 slides in the sliding groove 402 in a reciprocating manner, the rectangular frame 403 drives the push rod 501 to move synchronously, so that when the push rod 501 slides towards the left side, the cooling liquid is filled in the cooling tank 503, the push rod 501 extrudes the cooling liquid in the cooling tank 503 into the circulating pipe 506 from the liquid outlet joint 504 through the piston 502 for circulation, the circulating pipe 506 is embedded in the inner wall of the box body 1, the high temperature generated in the box body 1 is further cooled, and the heat dissipation performance is obviously improved.

The driving wheel 701 also rotates synchronously with the rotating shaft 301, so that the driving wheel 701 drives the two driven wheels 703 to rotate through the two belts 702 arranged in a staggered manner, the two driven wheels 703 drive the corresponding rotating rods 704 to rotate, and then the rotating rods 704 drive the cams 706 to periodically impact the filter screen frame 602, so that the filter screen frame 602 vibrates left and right in the grooves 604, dust and foreign matters on the filter screen frame 602 are shaken off, the filter screen holes in the filter screen frame 602 are prevented from being blocked by the dust and the foreign matters, and the heat dissipation efficiency in the box body 1 is influenced.

Meanwhile, the rotating shaft 301 drives the friction brush 801 to periodically rub against the rubber plate 802, when the rubber plate 802 rubs against the friction brush 801, the redundant positive charges of the negative charges of the rubber plate 802 are negative, and the redundant negative charges of the positive charges of the friction brush 801 are positive, so that dust entering the box body 1 is electrostatically adsorbed, and the dust is prevented from accumulating on the GPU element to generate faults such as short circuit.

The lateral wall of the box body 1 is provided with a box door, so that the GPU server is conveniently maintained.

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 as the technical solutions and the inventive concepts of the present invention within the technical scope of the present invention.

Claims

1. The GPU server is characterized by comprising a box body (1), a motor (2), a rotating mechanism (3), a reciprocating mechanism (4), a pushing mechanism (5), a ventilating mechanism (6), a knocking mechanism (7) and a dust removing mechanism (8), wherein the motor (2) is welded and fixed on the top wall of the box body (1), the rotating mechanism (3) is welded and fixed on the output end of the motor (2), the pushing mechanism (5) is welded and fixed on the side wall of the box body (1), the reciprocating mechanism (4) for driving the pushing mechanism (5) to move is welded and fixed on the inner wall of the box body (1), the ventilating mechanism (6) for circulating gas inside the box body (1) is arranged on the side wall of the box body (1), the knocking mechanism (7) for colliding and shaking the ventilating mechanism (6) is symmetrically and rotatably connected to the inner wall of the top of the box body (1), and the dust removing mechanism (8) for performing electrostatic adsorption on dust in the box body (1) is welded and fixed on the rotating mechanism (3);

the rotating mechanism (3) comprises a rotating shaft (301), a sector gear (302) and a negative pressure fan (303), the rotating shaft (301) is fixedly welded at the output end of the motor (2), one end, far away from the motor (2), of the rotating shaft (301) penetrates through the top wall of the box body (1) and then is rotatably connected to the inner wall of the bottom of the box body (1), the negative pressure fan (303) is fixedly welded on the side wall of the top of the rotating shaft (301), and the sector gear (302) is fixedly welded at the bottom of the rotating shaft (301);

the reciprocating mechanism (4) comprises a base (401), a sliding groove (402), a rectangular frame (403) and a rack (404), the base (401) is welded and fixed on the inner wall of the box body (1), the sliding groove (402) is formed in the inner wall of the base (401) along the horizontal direction, the rectangular frame (403) is connected in the sliding groove (402) in a sliding mode, the rack (404) is symmetrically welded and fixed on the inner side wall of the rectangular frame (403), and the rack (404) is meshed and connected with the sector gear (302);

the pushing mechanism (5) comprises a push rod (501), a piston (502), a cooling box (503), a liquid outlet joint (504), a liquid inlet joint (505) and a circulating pipe (506), the cooling box (503) is welded and fixed on the side wall of the box body (1), the push rod (501) is welded and fixed on the side wall of the rectangular frame (403), the piston (502) is welded and fixed on the end, far away from the rectangular frame (403), of the push rod (501) after sequentially penetrating through the inner walls of the box body (1) and the cooling box (503), the piston (502) is connected in the cooling box (503) in a sealing and sliding mode, the liquid outlet joint (504) and the liquid inlet joint (505) are arranged on the inner wall of one end of the cooling box (503), the circulating pipe (506) is embedded in the inner wall of the box body (1), and two ends of the circulating pipe (506) are fixedly communicated with the liquid outlet joint (504) and the liquid inlet joint (505) respectively;

the ventilation mechanism (6) comprises through holes (601), a filter screen frame (602), sliding blocks (603), grooves (604), springs (605) and air outlet holes (606), the through holes (601) are symmetrically formed in the side wall of the box body (1), the grooves (604) are symmetrically formed in the inner wall of each through hole (601), and each groove (604) is elastically connected with a sliding block (603) through a spring (605);

each sliding block (603) is connected in a corresponding groove (604) in a sliding manner, a filter screen frame (602) is welded and fixed together with the two sliding blocks (603), air outlet holes (606) are symmetrically formed in the top wall of the box body (1), and a filter screen is welded and fixed in the air outlet holes (606);

the knocking mechanism (7) comprises a driving wheel (701), a conveying belt (702), driven wheels (703), rotating rods (704), fixing blocks (705) and a cam (706), wherein the driving wheel (701) is fixedly welded on the rotating shaft (301), the rotating rods (704) are symmetrically and rotatably connected to the inner wall of the top of the box body (1), the fixing blocks (705) are symmetrically and fixedly welded to the inner wall of the box body (1), the bottom end of each rotating rod (704) is rotatably connected to the top of the fixing block (705), each rotating rod (704) is fixedly welded with a driven wheel (703), the two driven wheels (703) are respectively connected with the driving wheel (701) through the two conveying belts (702) which are arranged in a staggered mode, and the cam (706) is fixedly welded to the side wall of each rotating rod (704);

the dust removal mechanism (8) comprises a friction brush (801) and rubber plates (802), the friction brush (801) is made of fur materials, the friction brush (801) is symmetrically and fixedly connected to the side wall of the rotating shaft (301), and the rubber plates (802) are symmetrically welded and fixed to the inner wall of the box body (1).