CN115167639A

CN115167639A - Multi-point heat dissipation system and method for central storage of large-scale rendering cluster

Info

Publication number: CN115167639A
Application number: CN202210271813.9A
Authority: CN
Inventors: 张志杰
Original assignee: Beijing Hanxinsheng Technology Co ltd
Current assignee: Beijing Hanxinsheng Technology Co ltd
Priority date: 2022-03-18
Filing date: 2022-03-18
Publication date: 2022-10-11
Anticipated expiration: 2042-03-18
Also published as: CN115167639B

Abstract

The invention discloses a multipoint heat radiation system of a central memory of a large-scale rendering cluster, which comprises: the heat dissipation device comprises a rack, a first heat dissipation mechanism and a second heat dissipation mechanism, wherein a plurality of first waist-shaped grooves are formed in two sides of the rack, a plurality of second waist-shaped grooves are formed in the rear surface of the rack, and the multipoint moving heat dissipation mechanism is slidably mounted in the rack; the multipoint mobile heat dissipation mechanism comprises two symmetrically arranged plate bodies and a support rod fixedly connected between the two plate bodies; when the invention is used, the memory body of the cluster is arranged at the top of the support plate, the plate body and the heat dissipation fan are driven to move left and right at the bottom of the support plate by sliding the first cross rods in the first waist-shaped grooves at two sides of the rack, so that the left and right positions of the heat dissipation fan at the bottom of the support plate are adjusted, and meanwhile, the plate body and the heat dissipation fan are driven to move front and back at the bottom of the support plate by sliding the second cross rods in the second waist-shaped grooves, so that the left and right positions of the heat dissipation fan at the bottom of the support plate are adjusted.

Description

Multi-point heat dissipation system and method for central storage of large-scale rendering cluster

Technical Field

The invention belongs to the technical field of cluster memory heat dissipation, particularly relates to a multipoint heat dissipation system of a central memory of a large-scale rendering cluster, and particularly relates to a multipoint heat dissipation method of the central memory of the large-scale rendering cluster.

Background

The memory is a storage unit for storing programs and various data information. The storage can be divided into two major types, namely main storage or internal storage and auxiliary storage or external storage, the cluster storage is a storage pool which can provide a uniform access interface and a management interface for an application server by aggregating storage spaces in a plurality of storage devices, and the application can transparently access and utilize the disks on all the storage devices through the access interface, so that the performance of the storage devices and the utilization rate of the disks can be fully exerted. Data is stored and read from a plurality of storage devices according to certain rules so as to obtain higher concurrent access performance.

However, in the prior art, the multi-point heat dissipation performance of the central storage of the large-scale rendering cluster is not good, and especially when the storage cluster is installed on a rack, the multi-point heat dissipation performance cannot be specifically performed according to the heat generating points of the central storage, so that the heat dissipation performance is poor, and when the storage cluster is placed for a long time, dust is easily attached to the surface of the storage and the rack, so that the heat dissipation performance is further affected, and the abnormal use of the storage due to the fact that circuits are easily covered is caused.

Disclosure of Invention

The invention provides a multipoint heat dissipation system and a multipoint heat dissipation method for a central storage of a large-scale rendering cluster, which have the advantages that heat dissipation points can be flexibly adjusted, and heat dissipation and storage use are not easily influenced due to dust adhesion.

In order to achieve the technical purpose, the technical scheme adopted by the invention is as follows:

a multipoint heat dissipation system for a central storage of a mass rendering cluster, comprising: the device comprises a rack, a multipoint mobile heat dissipation mechanism and an auxiliary heat dissipation mechanism;

the heat dissipation device comprises a rack, a plurality of first waist-shaped grooves, a plurality of second waist-shaped grooves, a multi-point mobile heat dissipation mechanism and a heat dissipation mechanism, wherein the first waist-shaped grooves are formed in two sides of the rack;

wherein, the multiple spot removes heat dissipation mechanism is including plate body and the bracing piece of fixed connection between two plate bodies that two symmetries set up, the first horizontal pole of inside slidable mounting in first waist type groove, the inside slidable mounting in second horizontal pole in second waist type groove, first through-hole has been seted up to the both sides of plate body, the second through-hole has been seted up to the outer wall of bracing piece, first horizontal pole runs through first through-hole, the second horizontal pole runs through the second through-hole, first horizontal pole is located the top of second horizontal pole, radiator fan is installed at the top of plate body, install supplementary heat dissipation mechanism in the frame.

Adopt above-mentioned technical scheme's a multiple spot cooling system of central memory of large-scale rendering cluster comprises frame, multiple spot removal heat dissipation mechanism and supplementary heat dissipation mechanism, during the use, drive plate body and radiator fan through the first horizontal pole in the first waist type groove in slip frame both sides and control in the bottom of backup pad, thereby adjust radiator fan and control the position in the bottom of backup pad, and simultaneously, the second horizontal pole in the second waist type groove of sliding drives plate body and radiator fan and carries out the back-and-forth movement in the bottom of backup pad, thereby adjust radiator fan and control the position in the backup pad bottom.

Further, supplementary heat dissipation mechanism includes inlet air channel, inlet air channel install in the top of frame, the air intake has been seted up at the top of frame, the air intake is located inlet air channel's bottom, the fan is installed at inlet air channel's top, the welding that the both sides inner wall equidistance of frame was arranged has two sets of fixed blocks, every group in the quantity of fixed block is two, and every group the top of fixed block all is provided with the backup pad, the top nestification of backup pad has the heat dissipation net bars, the bottom fixedly connected with U-shaped of heat dissipation net bars is detained, the inside slidable mounting that the U-shaped was detained has the adhesive dust board, the backup pad top is provided with the memory body.

Furthermore, the front surface of the air inlet channel is fixedly connected with a fixing plate, and a plurality of air inlet holes are formed in the outer portion of the fixing plate.

Furthermore, the front surface of frame articulates through the hinge has the door plant, the front surface of door plant inlays and is equipped with the observation window.

Furthermore, the two ends of the first cross rod and the second cross rod are fixedly connected with handles.

Furthermore, a plurality of straight holes are arranged on the dust sticking plate.

Furthermore, two sides of the supporting plate are fixedly connected to the top of the fixing block through bolts.

Furthermore, four anti-slip pads are symmetrically and fixedly connected to the bottom of the rack.

The invention also provides a multipoint heat dissipation method of the central memory of the large-scale rendering cluster, which comprises the following steps:

s1, arranging a memory body of a cluster on the top of a supporting plate, and blowing the inside of a rack and the memory body by starting a fan and a cooling fan to dissipate heat by wind power;

s2, driving the plate body and the cooling fan to move left and right at the bottom of the supporting plate through first cross rods in first waist-shaped grooves on two sides of the sliding rack so as to adjust the left and right positions of the cooling fan at the bottom of the supporting plate, and simultaneously driving the plate body and the cooling fan to move front and back at the bottom of the supporting plate through second cross rods in second waist-shaped grooves so as to adjust the left and right positions of the cooling fan at the bottom of the supporting plate;

s3, blowing wind power into the air inlet channel under the action of the fan by starting the fan, enabling the wind to enter the rack from the air inlet after passing through the air inlet channel, and blowing dust off from the surface of the memory body while radiating the surface of the memory body in the rack;

and S4, after the dust is blown down, the dust enters the interior of the heat dissipation mesh grid on the supporting plate and is attached to the dust sticking plate, so that the dust on the rack and the memory body is reduced.

Further, in S4, the heat-dissipating wind power can continuously circulate up and down through a plurality of straight holes formed in the dust sticking plate.

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

1. when the heat dissipation device is used, the first cross rods in the first waist-shaped grooves on the two sides of the sliding rack drive the plate body and the heat dissipation fan to move left and right at the bottom of the supporting plate, so that the left and right positions of the heat dissipation fan at the bottom of the supporting plate are adjusted, meanwhile, the second cross rods in the second waist-shaped grooves drive the plate body and the heat dissipation fan to move front and back at the bottom of the supporting plate, so that the left and right positions of the heat dissipation fan at the bottom of the supporting plate are adjusted, and the central storage has a multi-point heat dissipation function and improves the heat dissipation effect through flexible change of the positions;

2. according to the invention, the fan is started, wind power is blown into the air inlet channel under the action of the fan, the wind enters the rack from the air inlet after passing through the air inlet channel, dust is blown off from the surface of the memory body while the surface of the memory body in the rack is cooled, the dust is blown off and then enters the interior of the cooling grid on the supporting plate and is attached to the dust sticking plate, so that the dust on the rack and the memory body is reduced, the surface cooling performance of the memory in the rack can be improved after the dust is removed and is attached and recovered on the dust sticking plate, and the abnormal use phenomenon of the memory caused by the influence of the dust is avoided.

Drawings

FIG. 1 is a schematic diagram of a multi-point heat dissipation system of a central memory according to the present invention;

FIG. 2 is a schematic structural diagram of another view of the multi-point heat dissipation system of the central memory according to the present invention;

FIG. 3 is a schematic cross-sectional view of a rack of the multi-point heat dissipation system of the central memory according to the present invention;

FIG. 4 is a schematic structural diagram of a plate and a support rod of the multi-point heat dissipation system of the central memory according to the present invention;

FIG. 5 is a schematic diagram of a supporting plate of the multi-point heat dissipation system of the central memory according to the present invention;

fig. 6 is a schematic cross-sectional view of a support plate in the multi-point heat dissipation system of the central memory according to the present invention.

The symbols in the figure illustrate: 1. a frame; 2. a first waist-shaped groove; 3. a handle; 4. a non-slip mat; 5. a door panel; 6. an observation window; 7. an air inlet hole; 8. a fixing plate; 9. a fan; 10. an air inlet channel; 11. a first cross bar; 12. a bolt; 13. a plate body; 14. a fixed block; 15. a heat-dissipating fan; 16. an air inlet; 17. a memory body; 18. a support plate; 19. a second cross bar; 20. a support bar; 21. a second waist-shaped groove; 22. a first through hole; 23. a second through hole; 24. a heat dissipation grid; 25. a dust adhering plate; 26. straight holes; 27. a U-shaped buckle.

Detailed Description

In order to facilitate understanding of those skilled in the art, the present invention is further described below with reference to the following examples and the accompanying drawings, which are not intended to limit the present invention.

Example one

As shown in fig. 1 to 6, the present embodiment provides a multi-point heat dissipation system for a central storage of a large-scale rendering cluster, which includes a rack 1, a multi-point moving heat dissipation mechanism, and an auxiliary heat dissipation mechanism.

Wherein, a plurality of first waist type grooves 2 have been seted up to the both sides of frame 1, and a plurality of second waist type grooves 21 have been seted up to the rear surface of frame 1, and the inside slidable mounting of frame 1 has multiple spot removal heat dissipation mechanism.

Multipoint movable heat dissipation mechanism is including plate body 13 and the bracing piece 20 of fixed connection between two plate bodies 13 that two symmetries set up, the first horizontal pole 11 of inside slidable mounting in first waist type groove 2, the inside slidable mounting in second horizontal pole 19 of second waist type groove 21, first through-hole 22 has been seted up to the both sides of plate body 13, second through-hole 23 has been seted up to the outer wall of bracing piece 20, first horizontal pole 11 runs through first through-hole 22, second horizontal pole 19 runs through second through-hole 23, first horizontal pole 11 is located the top of second horizontal pole 19, radiator fan 15 is installed at the top of plate body 13, install supplementary heat dissipation mechanism in frame 1.

The auxiliary heat dissipation mechanism comprises an air inlet channel 10, the air inlet channel 10 is installed at the top of the rack 1, an air inlet 16 is formed in the top of the rack 1, the air inlet 16 is located at the bottom of the air inlet channel 10, a fan 9 is installed at the top of the air inlet channel 10, two groups of fixing blocks 14 are welded on the inner walls of the two sides of the rack 1 in an equidistant mode, the number of the fixing blocks 14 in each group is two, a supporting plate 18 is arranged at the top of each group of fixing blocks 14, a heat dissipation mesh grid 24 is nested at the top of the supporting plate 18, a U-shaped buckle 27 is fixedly connected to the bottom of the heat dissipation mesh grid 24, a dust sticking plate 25 is installed inside the U-shaped buckle 27 in a sliding mode, a storage body 17 is arranged at the top of the supporting plate 18, the fan 9 is started through the technical scheme, and wind power is blown into the air inlet channel 10 under the action of the fan 9, wind enters the rack 1 from the air inlet 16 after passing through the air inlet channel 10, when heat dissipation is carried out on the surface of the memory body 17 in the rack 1, dust is blown off from the surface of the memory body 17, the dust enters the interior of the heat dissipation mesh grid 24 on the supporting plate 18 after being blown off and is attached to the dust adhering plate 25, the dust on the rack 1 and the memory body 17 is reduced, wherein the heat dissipation mesh grid 24 can improve the heat conduction efficiency, the heat dissipation effect is improved, the dust is removed, the dust is attached to and recovered on the dust adhering plate 25, meanwhile, the dust adhering plate 25 is convenient to clean or replace, the dust adhering plate 25 is slidably mounted in the U-shaped buckle 27, and the dust adhering plate 25 can be drawn out for cleaning or replacing after being used.

The front surface of the air inlet channel 10 is fixedly connected with a fixing plate 8, a plurality of air inlet holes 7 are formed in the outer portion of the fixing plate 8, and through the technical scheme, the air inlet holes 7 are formed in the outer portion of the fixing plate 8 and can extract external air to enter the air inlet channel 10 under the action of the fan 9.

Specifically, the front surface of the rack 1 is hinged with a door panel 5 through a hinge, and the front surface of the door panel 5 is embedded with an observation window 6, so that an operator can control the opening and closing of the front surface of the rack 1 through the door panel 5 and can directly observe the use condition of the memory body 17 in the rack 1 through the observation window 6.

The equal fixedly connected with handle 3 in both ends of first horizontal pole 11 and second horizontal pole 19 through increase handle 3 in first horizontal pole 11 and second horizontal pole 19 both ends, is more convenient for handheld first horizontal pole 11 of operating personnel and second horizontal pole 19.

Specifically, the dust-binding plate 25 is provided with a plurality of straight holes 26, and the straight holes 26 formed in the dust-binding plate 25 according to the above technical solution can guide the heat-dissipating wind to pass through the straight holes 26 for continuous circulation.

Specifically, the two sides of the supporting plate 18 are fixedly connected to the top of the fixing block 14 through the bolts 12, and according to the technical scheme, when the supporting plate 18 is installed, the bolts 12 penetrate through the two sides of the supporting plate 18 and are connected to the top of the fixing block 14, so that the supporting plate 18 is fixed.

Specifically, four non-slip mats 4 are fixedly connected to the bottom of the rack 1 symmetrically, and by means of the technical scheme, the friction force of the bottom of the rack 1 can be increased when the non-slip mats 4 are used, and the sliding phenomenon of the rack 1 is reduced.

Example two

The embodiment also provides a multipoint heat dissipation method for a central storage of a large-scale rendering cluster, which comprises the following steps:

s1, arranging a memory body 17 of a cluster on the top of a support plate 18, and blowing the inside of a rack 1 and the memory body 17 by starting a fan 9 and a cooling fan 15 to dissipate heat by wind power;

s2, driving the plate body 13 and the cooling fan 15 to move left and right at the bottom of the supporting plate 18 through the first cross rods 11 in the first waist-shaped grooves 2 at the two sides of the sliding frame 1, so as to adjust the left and right positions of the cooling fan 15 at the bottom of the supporting plate 18, and meanwhile, sliding the second cross rods 19 in the second waist-shaped grooves 21 to drive the plate body 13 and the cooling fan 15 to move front and back at the bottom of the supporting plate 18, so as to adjust the left and right positions of the cooling fan 15 at the bottom of the supporting plate 18;

s3, by starting the fan 9, wind power is blown into the air inlet channel 10 under the action of the fan 9, the wind enters the rack 1 from the air inlet 16 after passing through the air inlet channel 10, and dust is blown off from the surface of the memory body 17 while the heat of the surface of the memory body 17 in the rack 1 is dissipated;

and S4, after the dust is blown off, the dust enters the interior of the heat dissipation mesh grid 24 on the supporting plate 18 and is attached to the dust sticking plate 25, so that the dust on the rack 1 and the storage body 17 is reduced.

Specifically, in S4, the radiated wind power can continuously circulate up and down through the plurality of straight holes 26 formed in the dust-sticking plate 25.

The structure principle is as follows: the multipoint heat dissipation system of the central storage of the large-scale rendering cluster consists of a rack 1, a multipoint moving heat dissipation mechanism and an auxiliary heat dissipation mechanism, when in use, a first cross rod 11 in a first waist-shaped groove 2 at two sides of the rack 1 slides to drive a plate body 13 and a heat dissipation fan 15 to move left and right at the bottom of a support plate 18, so as to adjust the left and right positions of the heat dissipation fan 15 at the bottom of the support plate 18, meanwhile, a second cross rod 19 in a second waist-shaped groove 21 slides to drive the plate body 13 and the heat dissipation fan 15 to move front and back at the bottom of the support plate 18, so as to adjust the left and right positions of the heat dissipation fan 15 at the bottom of the support plate 18, through flexible change of positions, the central storage has the function of multipoint heat dissipation, the heat dissipation effect is improved, when an operator starts a fan 9, can blow in inlet air channel 10 with wind-force under the effect of fan 9, wind gets into in the frame 1 from air intake 16 after through inlet air channel 10, carry out the heat dissipation to memory body 17 surface in the frame 1 simultaneously, blow off the dust from memory body 17 surface, it is inside to get into the heat dissipation net bars 24 on the backup pad 18 after the dust blows off, and attach to the sticky dust board 25, a dust for reducing on frame 1 and memory body 17, wherein, heat dissipation net bars 24 can improve the heat conduction efficiency, increase the radiating effect, through getting rid of the dust, and attach the dust and retrieve on sticky dust board 25, and simultaneously, for the convenience of the cleanness or the change of sticky dust board 25, with the inside of sticky dust board 25 slidable mounting at U-shaped knot 27, can take out sticky dust board 25 after the use and clean or change.

The multi-point heat dissipation system and method for the central storage of the large-scale rendering cluster provided by the present application are described in detail above. The description of the specific embodiments is only intended to facilitate the understanding of the method of the present application and its core concepts. It should be noted that, for those skilled in the art, it is possible to make several improvements and modifications to the present application without departing from the principle of the present application, and such improvements and modifications also fall within the scope of the claims of the present application.

Claims

1. A multipoint heat dissipation system for a central storage of a mass rendering cluster, comprising:

the heat dissipation device comprises a rack (1), wherein a plurality of first waist-shaped grooves (2) are formed in two sides of the rack (1), a plurality of second waist-shaped grooves (21) are formed in the rear surface of the rack (1), and a multi-point moving heat dissipation mechanism is slidably mounted in the rack (1);

wherein, the multiple spot removes heat dissipation mechanism is including plate body (13) and bracing piece (20) of fixed connection between two plate bodies (13) that two symmetries set up, the first horizontal pole (11) of inside slidable mounting of first waist type groove (2), the inside slidable mounting in second horizontal pole (19) of second waist type groove (21), first through-hole (22) have been seted up to the both sides of plate body (13), second through-hole (23) have been seted up to the outer wall of bracing piece (20), first horizontal pole (11) run through first through-hole (22), second horizontal pole (19) run through second through-hole (23), first horizontal pole (11) are located the top of second horizontal pole (19), radiator fan (15) are installed at the top of plate body (13), install supplementary heat dissipation mechanism on frame (1).

2. The multi-drop heat dissipation system for a central storage of a mass rendering cluster of claim 1, wherein: supplementary heat dissipation mechanism includes inlet air channel (10), inlet air channel (10) install in the top of frame (1), air intake (16) have been seted up at the top of frame (1), air intake (16) are located the bottom of inlet air channel (10), fan (9) are installed at the top of inlet air channel (10), the welding that the both sides inner wall equidistance of frame (1) was arranged has two sets of fixed blocks (14), and in every group the quantity of fixed block (14) is two, and every group the top of fixed block (14) all is provided with backup pad (18), the top of backup pad (18) has nested heat dissipation net bars (24), the bottom fixedly connected with U-shaped of heat dissipation net bars (24) detains (27), the inside slidable mounting that U-shaped detained (27) has dust-binding plate (25), backup pad (18) top is provided with memory body (17).

3. The multi-drop heat dissipation system for a hub memory of a mass rendering cluster of claim 2, wherein: the front surface of the air inlet channel (10) is fixedly connected with a fixing plate (8), and a plurality of air inlet holes (7) are formed in the outer portion of the fixing plate (8).

4. The multi-drop heat dissipation system for a hub memory of a mass rendering cluster of claim 1, wherein: the front surface of the frame (1) is hinged with a door panel (5) through a hinge, and the front surface of the door panel (5) is embedded with an observation window (6).

5. The multi-drop heat dissipation system for a hub memory of a mass rendering cluster of claim 1, wherein: the two ends of the first cross rod (11) and the second cross rod (19) are fixedly connected with handles (3).

6. The multi-drop heat dissipation system for a hub memory of a mass rendering cluster of claim 2, wherein: the dust sticking plate (25) is provided with a plurality of straight holes (26).

7. The multi-drop heat dissipation system for a hub memory of a mass rendering cluster of claim 2, wherein: two sides of the supporting plate (18) are fixedly connected to the top of the fixing block (14) through bolts (12).

8. The multi-drop heat dissipation system for a hub memory of a mass rendering cluster of claim 1, wherein: the bottom of the frame (1) is symmetrically and fixedly connected with four anti-slip pads (4).

9. A multipoint heat dissipation method for a central storage of a large-scale rendering cluster is characterized by comprising the following steps:

s1, arranging a memory body (17) of a cluster at the top of a support plate (18), and blowing the inside of a rack (1) and the memory body (17) by starting a fan (9) and a cooling fan (15) to dissipate heat by wind power;

s2, driving a plate body (13) and a cooling fan (15) to move left and right at the bottom of a supporting plate (18) through first cross rods (11) in first waist-shaped grooves (2) on two sides of a sliding rack (1), so as to adjust the left and right positions of the cooling fan (15) at the bottom of the supporting plate (18), and meanwhile, sliding a second cross rod (19) in a second waist-shaped groove (21) to drive the plate body (13) and the cooling fan (15) to move front and back at the bottom of the supporting plate (18), so as to adjust the left and right positions of the cooling fan (15) at the bottom of the supporting plate (18);

s3, blowing wind power into the air inlet channel (10) under the action of the fan (9) by starting the fan (9), enabling the wind to enter the rack (1) from the air inlet (16) after passing through the air inlet channel (10), and blowing dust off from the surface of the memory body (17) while radiating the surface of the memory body (17) in the rack (1);

and S4, after the dust is blown down, the dust enters the interior of the heat dissipation mesh grid (24) on the supporting plate 18 and is attached to the dust sticking plate (25) to reduce the dust on the rack (1) and the storage body (17).

10. The method of multipoint heat dissipation in a central storage of a mass rendering cluster of claim 9, wherein: in S4, the heat-dissipating wind power can continuously circulate up and down through a plurality of straight holes (26) formed in the dust sticking plate (25).