CN110989788A - Big data storage server - Google Patents

Abstract

The invention discloses a big data storage server, which comprises a plurality of installation units, wherein each installation unit comprises a base and a plurality of installation boxes, each installation box is provided with a sealing door, the installation boxes are arranged on the base, and the installation boxes are arranged on the base in a regular polygon shape; the back of each mounting box body is provided with an air suction channel and an air inlet pipeline which are communicated with the mounting box body; an apron is installed at the top of installation box, the top of apron is equipped with exhaust duct, intake stack, exhaust duct, intake stack all through the support frame with fixed mounting between the apron. When the air inlet device is used, the air inlet fan inflates air towards the inside of the air inlet pipeline, the air enters the installation box body, the exhaust fan exhausts the air to the outside at the same time, the air in the installation box body is exhausted from the exhaust pipeline to the inside of the installation box body, and the heat on the electronic equipment is rapidly dissipated.

Description

Big data storage server

Technical Field

The invention relates to the technical field of servers, in particular to a big data storage server.

Background

The big data storage servers are operated by computers, most of the big data storage devices used at present are cooled by cold air, but in a data center, the heat dissipation requirements of the high heat flow density servers cannot be met by air cooling, the power consumption of equipment air conditioning equipment is high, and the phenomenon of aggregation easily occurs in the static state of air around the surface of electronic equipment, so that the big data storage server is provided.

Disclosure of Invention

The invention aims to solve the defects in the prior art and provides a large data storage server.

In order to achieve the purpose, the invention adopts the following technical scheme: a big data storage server comprises a plurality of installation units, wherein each installation unit comprises a base and a plurality of installation boxes, each installation box is provided with a sealing door, the installation boxes are installed on the bases, and the installation boxes are arranged on the bases in a regular polygon shape; the back of each mounting box body is provided with an air suction channel and an air inlet pipeline which are communicated with the mounting box body;

the top of the mounting box body is provided with a cover plate, an exhaust pipeline and an air inlet pipeline are arranged above the cover plate, the exhaust pipeline and the air inlet pipeline are fixedly mounted with the cover plate through a support frame, and the air inlet pipeline as well as an air suction channel and the exhaust pipeline are connected through connecting pipes;

one end of the air inlet pipeline is connected with an air inlet fan through a pipeline, and one end of the air outlet pipeline is connected with an air outlet fan through a pipeline;

the mounting units are arranged in rows, and the corresponding exhaust pipelines are connected with the exhaust pipeline and the corresponding air inlet pipelines are connected with the air inlet pipeline.

Preferably, a plurality of layers of supporting structures are arranged in the installation box body, each layer of supporting structure comprises two U-shaped sliding grooves, openings of the U-shaped sliding grooves are oppositely arranged, and the U-shaped sliding grooves are fixed on two side surfaces in the installation box body; a U-shaped mounting plate is arranged between the U-shaped sliding grooves, and two ends of the U-shaped mounting plate are just arranged in the two U-shaped sliding grooves, so that the U-shaped mounting plate can be drawn in and out of the U-shaped sliding grooves;

an air channel is arranged between each layer of supporting structures, the air channel is a rectangular channel, the width of the air channel is consistent with the width of the inner cavity of the installation box body, the opening of the air channel is positioned right below one end of the U-shaped installation plate, and the air channel penetrates through and is fixed on the back of the installation box body;

the air outlet pipeline is connected to the back of the installation box body corresponding to the U-shaped installation plate, and the air outlet pipeline is connected with the air suction channel and the air inlet pipeline through air flow pipelines.

Preferably, the top surface and the bottom surface of two sides of the U-shaped chute are both provided with rectangular mounting openings, a support plate is accommodated in each rectangular mounting opening, two ends of each support plate are both arc surfaces, the top of each support plate is provided with a strip-shaped through groove, a plurality of walking gears are mounted at intervals along the length direction of each strip-shaped through groove, the walking gears leak out of the strip-shaped through grooves, and the walking gears are connected with the support plates through rotating shafts; the springs are arranged at equal intervals at the bottom of the supporting plate, the springs are fixed with the bottom of the rectangular mounting opening, and the supporting plate is exposed outside the rectangular mounting opening under the support of the springs;

limiting grooves are formed in the upper end face and the lower end face of the inner cavity of the U-shaped sliding groove and matched with the walking gear.

Preferably, two at least blind holes have all been seted up on the terminal surface of the both sides of U type mounting panel, all be equipped with a locking screw in the center department of every blind hole, locking screw runs through to the other end of U type mounting panel from the center of blind hole, installs the knob in the one end that locking screw is close to the blind hole, inside the blind hole just can be arranged in with the blind hole size matching of knob, locking screw's the other end and the back threaded connection of installation box.

Preferably, the bottom of one end of the ventilation duct close to the sealing door is provided with an arc-shaped air deflector which is bent upwards, the top of the arc-shaped air deflector is just positioned at the bottom of the U-shaped mounting plate, and the arc-shaped air deflector is not contacted with the U-shaped mounting plate;

and a plurality of rubber sealing gaskets corresponding to the arc-shaped air deflectors are arranged on the sealing door.

Preferably, the tail end of the air channel, the two ends of the airflow pipeline and the tail end of the air outlet pipeline are respectively provided with a connecting skirt, the connecting skirts are mutually overlapped and connected through bolts, ventilation openings corresponding to the airflow pipeline are formed in the air suction channel and the air inlet pipeline, the ventilation openings are in butt joint with the tail end port of the airflow pipeline, and the connecting skirts are fastened with the air suction channel and the air inlet pipeline through bolts.

Preferably, the connecting pipe is a hose, the one end of connecting pipe is connected at the top of intake stack and induced draft passageway, and the other end all is connected with the pipe joint, the pipe joint is installed on exhaust duct, intake stack.

Preferably, the bottom of each mounting box body is provided with a rubber pad.

Preferably, the sealing door is connected with the installation box body through a built-in lock.

Preferably, the two sides of the back of the installation box body are connected through a sealing plate.

When the big data storage server provided by the invention is used, the air inlet fan inflates air towards the inside of the air inlet pipeline, airflow enters the inside of the installation box body through the air inlet pipeline, the exhaust fan exhausts air to the outside at the same time, the air in the installation box body is exhausted from the exhaust pipeline to the inside of the installation box body, new air and old air are exchanged, heat on electronic equipment is rapidly dissipated, the temperature reduction effect is better compared with that of the traditional big data storage server, and the service life of the electronic equipment can be effectively prolonged.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

fig. 1 is a schematic structural diagram of a big data storage server according to the present invention.

Fig. 2 is a schematic diagram of an arrangement structure of an installation box of a large data storage server according to the present invention.

Fig. 3 is a front view of an installation box of a large data storage server according to the present invention.

Fig. 4-5 are rear views of a large data storage server according to the present invention from different angles.

Fig. 6 is a schematic structural diagram of an installation box of a large data storage server according to the present invention.

Fig. 7 is a schematic structural diagram of a U-shaped mounting plate of a large data storage server according to the present invention.

Fig. 8 is a cross-sectional view of a mounting box of a large data storage server according to the present invention.

Fig. 9 is a schematic structural diagram of an air duct and an airflow duct, and an air outlet duct and an airflow duct of a big data storage server according to the present invention.

Labeled as in the figure: the air duct structure comprises a base 1, a rubber pad 2, a U-shaped mounting plate 3, an air duct 4, an arc-shaped air deflector 5, a sealing door 6, a rubber sealing gasket 7, a U-shaped sliding groove 8, a sealing plate 9, a limiting groove 10, an air suction channel 11, an air inlet pipeline 12, an air outlet pipeline 13, a ventilation opening 14, a mounting box body 15, an air exhaust pipeline 16, an air inlet pipeline 17, a support frame 18, a connecting pipe 19, a knob 20, a blind hole 21, a support plate 22, a walking gear 23, a rectangular mounting opening 24, a spring 25, an air flow pipeline 26, a cover plate 27, a pipeline joint 28, a strip-shaped through groove 29.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is further described in detail below with reference to examples and accompanying drawings, and the exemplary embodiments and descriptions thereof are only used for explaining the present invention and are not meant to limit the present invention.

The structural features of the present invention will now be described in detail with reference to the accompanying drawings.

Referring to fig. 1-9, a big data storage server comprises a plurality of installation units, wherein each installation unit comprises a base 1 and a plurality of installation boxes 15, each installation box 15 is provided with a sealing door 6, the installation boxes 15 are installed on the base 1, and the installation boxes 15 are arranged on the base 1 in a regular polygon shape; the back of each mounting box body 15 is provided with an air suction channel 11 and an air inlet pipeline 12, and the air suction channel 11 and the air inlet pipeline 12 are communicated with the mounting box bodies 15;

a cover plate 27 is installed at the top of the installation box body 15, an exhaust duct 16 and an air inlet duct 17 are arranged above the cover plate 27, the exhaust duct 16 and the air inlet duct 17 are fixedly installed between the cover plate 27 and the support frame 18, and the air inlet duct 12 and the air inlet duct 17, and the air suction channel 11 and the exhaust duct 16 are connected through connecting pipes 19;

one end of the air inlet pipeline 17 is connected with an air inlet fan through a pipeline, and one end of the air outlet pipeline 16 is connected with an air outlet fan through a pipeline;

the installation units are arranged in rows, and the corresponding exhaust pipelines 16 are connected with the exhaust pipelines 16, and the corresponding air inlet pipelines 17 are connected with the air inlet pipelines 17.

Specifically, when the present invention is used, the air inlet fan inflates air towards the inside of the air inlet duct 17, so that air flow enters the inside of the installation box body 15 through the air inlet duct 17, the air outlet fan exhausts air to the outside at the same time, so that the air in the installation box body 15 is exhausted from the air outlet duct 16 to the inside of the installation box body 15, and new air and old air are exchanged.

Further, as shown in fig. 3 and 6, a plurality of layers of support structures are arranged inside the installation box body 15, each layer of support structure includes two U-shaped chutes 8, the two U-shaped chutes 8 on each layer are stacked, openings of the U-shaped chutes 8 are oppositely arranged, and the U-shaped chutes 8 are fixed on two side surfaces inside the installation box body 15; the U-shaped mounting plates 3 are arranged between the U-shaped sliding grooves 8, and two ends of each U-shaped mounting plate 3 are just arranged in the two U-shaped sliding grooves 8, so that the U-shaped mounting plates 3 can be drawn in and out of the U-shaped sliding grooves 8; in the actual application process, the U-shaped mounting plate 3 is internally used for mounting equipment related to big data;

the ventilating duct 4 is arranged between every two layers of supporting structures, the ventilating duct 4 is a rectangular channel, the width of the ventilating duct 4 is consistent with the width of an inner cavity of the installation box body 15, the opening of the ventilating duct 4 is positioned right below one end of the U-shaped installation plate 3, and the ventilating duct 4 penetrates and is fixed on the back face of the installation box body 15;

air-out pipeline 13, every all are connected on the back of the installation box 15 that U type mounting panel 3 corresponds between air-out pipeline 13 and the passageway 11 that induced drafts and between ventiduct 4 and the intake stack 12 all through airflow pipeline 26 connection.

Specifically, when the air conditioner is used, air blown by the air inlet pipeline 12 is directly dispersed into a plurality of air flows by the plurality of air channels 4, each air flow is directly blown to the opening position of the U-shaped mounting plate 3, the air outlet pipeline 13 sucks the air flow all the time, so that the air flow entering each U-shaped mounting plate 3 from the air outlet pipeline 13 is directly sucked from the air outlet pipeline 13, the air is exchanged, and the heat on the surface of the equipment is taken away in the air flowing process.

Further, as shown in fig. 7, rectangular mounting openings 24 are formed in the top surface and the bottom surface of each of two sides of the U-shaped chute 8, a support plate 22 is disposed in each rectangular mounting opening 24, two ends of each support plate 22 are arc surfaces, a strip-shaped through groove 29 is formed in the top of each support plate 22, a plurality of walking gears 23 are mounted at intervals along the length direction of each strip-shaped through groove 29, the walking gears 23 are leaked outside the strip-shaped through grooves 29, and the walking gears 23 are connected with the support plates 22 through rotating shafts; the springs 25 arranged at equal intervals are mounted at the bottoms of the supporting plates 22, the springs 25 are fixed with the bottoms of the rectangular mounting openings 24, and the supporting plates 22 are exposed outside the rectangular mounting openings 24 under the support of the springs 25;

limiting grooves 10 are formed in the upper end face and the lower end face of the inner cavity of the U-shaped sliding groove 8, and the limiting grooves 10 are matched with the walking gear 23.

Specifically, when U type mounting panel 3 is towards the inside of U type spout 8 when inserting, the both ends of backup pad 22 are the arc surface in order to prevent backup pad 22 and the problem that U type spout 8 took place to block, decurrent extrusion pressure degree is received to backup pad 22 this moment, let backup pad 22 towards the inside shrink of rectangle installing port 24, because spring 25's setting, make walking gear 23 offset with spacing groove 10 all the time, let U type mounting panel 3 stable install inside U type spout 8, the spring 25 that sets up simultaneously can also take out the in-process of taking out at U type mounting panel 3 and play good absorbing effect, can effectively protect the inside device of U type mounting panel 3 not damaged.

Further, as shown in fig. 7, at least two blind holes 21 are formed in the end faces of the two sides of the U-shaped mounting plate 3, a locking screw 30 is arranged at the center of each blind hole 21, the locking screw 30 penetrates through the center of each blind hole 21 to the other end of the U-shaped mounting plate 3, a knob 20 is mounted at one end, close to the blind hole 21, of the locking screw 30, the knob 20 is matched with the blind hole 21 in size and can be placed inside the blind hole 21, and the other end of the locking screw 30 is in threaded connection with the back face of the mounting box body 15.

Specifically, when the U-shaped mounting plate 3 is completely located inside the U-shaped sliding groove 8, in order to prevent the U-shaped mounting plate 3 from being disengaged from the U-shaped sliding groove 8, the locking screw 30 and the mounting box 15 can be fastened by threads, and the knob 20 is provided to facilitate the rotation of the locking screw 30.

Further, the bottom of one end, close to the sealing door 6, of the air duct 4 is provided with an arc-shaped air deflector 5 which is bent upwards, the top of the arc-shaped air deflector 5 is just positioned at the bottom of the U-shaped mounting plate 3, and the arc-shaped air deflector 5 is not contacted with the U-shaped mounting plate 3;

and a plurality of rubber gaskets 7 corresponding to the arc-shaped air deflector 5 are arranged on the sealing door 6.

As shown in fig. 2 and 3, when the sealing door 6 is closed, the rubber gasket 7 abuts against the arc-shaped air deflector 5, so that a sealing state is formed between the outer side of the arc-shaped air deflector 5 and the sealing door 6, and the air flowing backwards from the arc-shaped air deflector 5 is directly blown into the U-shaped mounting plate 3.

Further, as shown in fig. 9, the end of the air duct 4, the two ends of the airflow duct 26, and the end of the air outlet duct 13 are respectively provided with a connecting skirt 31, the connecting skirts 31 are mutually overlapped and connected through bolts, the air suction channel 11 and the air inlet duct 12 are respectively provided with a vent 14 corresponding to the airflow duct 26, the vent 14 is butted with the end port of the airflow duct 26, and the connecting skirt 31 is fastened with the air suction channel 11 and the air inlet duct 12 through bolts, so that the disassembly and the assembly are convenient.

Furthermore, the connecting pipe 19 is a hose, one end of the connecting pipe 19 is connected to the top of the air inlet pipe 12 and the air suction channel 11, the other end of the connecting pipe is connected to a pipe joint 28, and the pipe joint 28 is installed on the air exhaust pipe 16 and the air inlet pipe 17. In use, since the air inlet duct 12 and the air suction passage 11 are plural, the connection pipe 19 is a hose for easy installation.

Further, a rubber pad 2 is mounted at the bottom of each mounting box 15.

Furthermore, the sealing door 6 is connected with the installation box body 15 through a built-in lock.

Furthermore, the two sides of the back of the installation box body 15 are connected through a sealing plate 9.

In the present invention, the air circulates in a path as shown in fig. 8, and the direction of the arrows represents the flow direction of the air.

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 the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims (10)

1. The big data storage server is characterized by comprising a plurality of installation units, wherein each installation unit comprises a base (1) and a plurality of installation boxes (15), each installation box (15) is provided with a sealing door (6), the installation boxes (15) are installed on the base (1), and the installation boxes (15) are arranged on the base (1) in a regular polygon shape; the back of each mounting box body (15) is provided with an air suction channel (11) and an air inlet pipeline (12), and the air suction channel (11) and the air inlet pipeline (12) are communicated with the mounting box bodies (15);

a cover plate (27) is installed at the top of the installation box body (15), an exhaust duct (16) and an air inlet duct (17) are arranged above the cover plate (27), the exhaust duct (16) and the air inlet duct (17) are fixedly installed between the cover plate (27) through a support frame (18), and the air inlet duct (12) and the air inlet duct (17) and the air suction channel (11) and the exhaust duct (16) are connected through connecting pipes (19);

one end of the air inlet pipeline (17) is connected with an air inlet fan through a pipeline, and one end of the air outlet pipeline (16) is connected with an air outlet fan through a pipeline;

the mounting units are arranged in rows, and the corresponding exhaust pipelines (16) are connected with the exhaust pipelines (16) and the corresponding air inlet pipelines (17) are connected with the air inlet pipelines (17).

2. A big data storage server according to claim 1, wherein multiple layers of supporting structures are arranged inside the installation box body (15), each layer of supporting structure comprises two U-shaped sliding chutes (8), the openings of the U-shaped sliding chutes (8) are oppositely arranged, and the U-shaped sliding chutes (8) are fixed on two sides inside the installation box body (15); a U-shaped mounting plate (3) is arranged between the U-shaped sliding grooves (8), and two ends of the U-shaped mounting plate (3) are just arranged in the two U-shaped sliding grooves (8), so that the U-shaped mounting plate (3) can be drawn in and out of the U-shaped sliding grooves (8);

the ventilating duct (4) is arranged between every two layers of supporting structures, the ventilating duct (4) is a rectangular channel, the width of the ventilating duct is consistent with the width of an inner cavity of the mounting box body (15), an opening of the ventilating duct (4) is positioned under one end of the U-shaped mounting plate (3), and the ventilating duct (4) penetrates and is fixed on the back of the mounting box body (15);

all connect air-out pipeline (13), every on the back of the installation box (15) that U type mounting panel (3) corresponds air-out pipeline (13) and induced draft between passageway (11) and between ventiduct (4) and intake stack (12) all are connected through air flow pipeline (26).

3. The big data storage server according to claim 2, wherein rectangular mounting openings (24) are formed in the top surface and the bottom surface of each of two sides of the U-shaped sliding groove (8), a support plate (22) is arranged in each rectangular mounting opening (24), both ends of each support plate (22) are arc surfaces, a strip-shaped through groove (29) is formed in the top of each support plate (22), a plurality of walking gears (23) are mounted at intervals along the length direction of the strip-shaped through grooves (29), the walking gears (23) are leaked outside the strip-shaped through grooves (29), and the walking gears (23) are connected with the support plates (22) through rotating shafts; the springs (25) which are arranged at equal intervals are mounted at the bottoms of the supporting plates (22), the springs (25) are fixed with the bottoms of the rectangular mounting openings (24), and the supporting plates (22) are exposed outside the rectangular mounting openings (24) under the support of the springs (25);

limiting grooves (10) are formed in the upper end face and the lower end face of the inner cavity of the U-shaped sliding groove (8), and the limiting grooves (10) are matched with the walking gear (23).

4. The big data storage server according to claim 2, wherein the end faces of the two sides of the U-shaped mounting plate (3) are provided with at least two blind holes (21), the center of each blind hole (21) is provided with a locking screw (30), the locking screw (30) penetrates through the other end of the U-shaped mounting plate (3) from the center of the blind hole (21), one end of the locking screw (30) close to the blind hole (21) is provided with a knob (20), the knob (20) is matched with the blind hole (21) in size and can be placed in the blind hole (21), and the other end of the locking screw (30) is in threaded connection with the back face of the mounting box body (15).

5. The big data storage server according to claim 2, wherein an arc-shaped air deflector (5) which is bent upwards is mounted at the bottom of one end of the air duct (4) close to the sealing door (6), the top of the arc-shaped air deflector (5) is just positioned at the bottom of the U-shaped mounting plate (3), and the arc-shaped air deflector (5) is not in contact with the U-shaped mounting plate (3);

and a plurality of rubber sealing gaskets (7) corresponding to the arc-shaped air deflector (5) are arranged on the sealing door (6).

6. The big data storage server according to claim 2, wherein the connecting skirts (31) are respectively arranged at the tail end of the air duct (4), the two ends of the airflow pipeline (26) and the tail end of the air outlet pipeline (13), the connecting skirts (31) are mutually overlapped and connected through bolts, the air suction channel (11) and the air inlet pipeline (12) are respectively provided with a ventilation opening (14) corresponding to the airflow pipeline (26), the ventilation openings (14) are butted with the tail end ports of the airflow pipeline (26), and the connecting skirts (31) are fastened with the air suction channel (11) and the air inlet pipeline (12) through bolts.

7. The big data storage server according to claim 1, wherein the connection pipe (19) is a flexible pipe, one end of the connection pipe (19) is connected to the top of the air intake duct (12) and the air suction channel (11), the other end is connected to a duct joint (28), and the duct joint (28) is installed on the air exhaust duct (16) and the air intake duct (17).

8. A large data storage server as claimed in claim 1, characterised in that the bottom of each mounting box (15) is fitted with a rubber pad (2).

9. A mass data storage server according to claim 1, wherein the sealed door (6) is connected to the mounting enclosure (15) by a mortice lock.

10. A mass data storage server according to claim 1, wherein the mounting boxes (15) are connected on both sides of the back side by sealing plates (9).

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