CN218587522U - A rotatory knockout for liquid cooling rack - Google Patents

Abstract

The utility model discloses a rotatory knockout for liquid cooling rack, construct including main water supply pipe, a plurality of group's reposition of redundant personnel pipeline, a plurality of group installation sleeve and a plurality of group liquid, main water supply pipe sets up inside the liquid cooling rack, a plurality of groups reposition of redundant personnel pipeline, the equal equidistance fixed connection of a plurality of group installation sleeve are at main water supply pipe's top. This a rotatory knockout for liquid cooling rack passes through the installed part, the gag lever post reaches the cooperation between the piece of drawing and uses, can fix the assembly of branch liquid mechanism on the reposition of redundant personnel pipeline, carry the cooling water through the intubate and divide the liquid casing in, and promote the slurcam and divide the synchronous rotation of liquid casing through intubate top spun cooling water, and then realize the rotation of a plurality of groups extension pipe, this a rotatory knockout for liquid cooling rack has effectively improved the radiating homogeneity of electronic equipment liquid cooling, the drive method is simple, can drive when the cooling water transportation divide liquid mechanism rotatory, the cost is reduced, the dismouting is simple, the practicability is improved.

Description

Rotary liquid separator for liquid cooling cabinet

Technical Field

The utility model relates to a liquid cooling heat dissipation technical field specifically is a rotatory knockout for liquid cooling rack.

Background

Electronic devices often have heat dissipation requirements due to heat generation during operation.

For example, a single-phase immersion type liquid cooling heat dissipation method has been used, in which electronic equipment is placed in a liquid cooling cabinet having an upper inlet and a lower inlet, and cooling liquid enters the electronic equipment from the inlet at the lower end of the cabinet, and then flows out from the outlet at the upper end of the cabinet, so that the cooling liquid exchanges heat with the electronic equipment in a circulating flow, thereby dissipating heat from the electronic equipment.

However, in the above solution, the cooling liquid usually enters from one side of the liquid-cooled cabinet, and at this time, for the same horizontal position, the heat dissipation between the electronic devices or between different positions of the same electronic device is not uniform, and in order to maintain the overall heat dissipation requirement of the electronic device, the prior art usually needs to increase the cooling capacity of the cooling liquid, which causes a waste of resources.

Prior publication No. CN 202120125087.0: a rotatory knockout and liquid cooling rack for liquid cooling rack has solved the extravagant technical problem of resource that leads to when uneven because the liquid cooling heat dissipation, has realized improving the radiating homogeneity of electronic equipment liquid cooling, reduce the technological effect of extravagant resource, but this a rotatory knockout and liquid cooling rack for liquid cooling rack when using, need drive the liquid cavity at the uniform velocity rotation through external drive units such as driving motor, just so need set up external drive unit in the liquid cooling rack, the external drive unit of one party generates heat and influences the cooling environment in the liquid cooling rack, the external drive unit of the other party sets up with high costs, the dismouting maintenance is inconvenient, has reduced the practicality.

In view of the above, a rotary liquid distributor for a liquid cooling cabinet is designed.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a rotatory knockout for liquid cooling rack to current rotatory knockout and the liquid cooling rack for the liquid cooling rack that proposes in solving above-mentioned background art when using, influence the cooling environment in the liquid cooling rack, the outer unit that drives sets up with high costs, dismouting maintenance inconvenience, reduced the problem of practicality.

In order to achieve the purpose, the utility model provides a rotary liquid separator for a liquid cooling cabinet, which comprises a main water supply pipeline, a plurality of component flow pipelines, a plurality of component mounting sleeves and a plurality of component liquid mechanisms;

the main water supply pipeline is arranged inside the liquid cooling cabinet;

the groups of the diversion pipelines and the groups of the mounting sleeves are fixedly connected to the top of the main water supply pipeline at equal intervals;

the plurality of component liquid mechanisms are respectively connected to the plurality of component flow pipelines.

Preferably, an electric control valve is installed on the shunt pipeline.

Preferably, divide liquid mechanism including dividing liquid casing, intubate, waterproof bearing and a plurality of groups extension pipe, wherein:

the inner top surface of the liquid separation shell is in a regular annular array and is fixedly connected with a plurality of groups of push plates;

the waterproof bearing is fixedly arranged in the bottom of the liquid separation shell in a penetrating manner;

the insertion pipe is fixed in the inner ring of the waterproof bearing, and the lower end of the insertion pipe is connected into the top of the shunt pipeline;

and the plurality of groups of extension pipes are fixedly connected to the surface of the liquid-separating shell in a regular annular array.

Preferably, the upper end of intubate is "C" type structure, and the external diameter length of intubate lower extreme matches with the internal diameter length of reposition of redundant personnel pipeline, and the lower extreme outside cover of intubate is equipped with sealed cushion.

Preferably, a plurality of groups of inclined pipes are fixedly connected to the top of the extension pipe at equal intervals.

Preferably, divide liquid mechanism still includes installed part, gag lever post and draws the piece, wherein:

the lower end of the mounting piece is connected to the inner side of the mounting sleeve in a clearance fit manner;

the limiting rod is in clearance fit and inserted connection in the mounting piece and one side of the mounting sleeve;

the pull block is fixedly connected to one end of the limiting rod, and a spring is fixedly connected between the pull block and the surface of the mounting sleeve.

Preferably, divide liquid mechanism still includes a plurality of groups of support frames and ring channel, wherein:

the annular groove is formed in the surface of the middle part of the insertion pipe;

the support frames are fixedly connected to the bottom of the liquid separating shell in a regular annular array mode, a rotary groove is formed in one side, close to the insertion pipe, of the lower end of each support frame, a ball is connected to the rotary groove in a rotating mode, and the ball is movably connected into the annular groove.

Preferably, the diameter length of the ball is greater than the opening width of the rotary slot.

Compared with the prior art, the beneficial effects of the utility model are that: this a rotatory knockout for liquid cooling rack passes through the installed part, the gag lever post reaches the cooperation between the piece of drawing and uses, can fix the assembly of branch liquid mechanism on the reposition of redundant personnel pipeline, carry the cooling water through the intubate and divide the liquid casing in, and promote the slurcam and divide the synchronous rotation of liquid casing through intubate top spun cooling water, and then realize the rotation of a plurality of groups extension pipes, this a rotatory knockout for liquid cooling rack has effectively improved the radiating homogeneity of electronic equipment liquid cooling, drive scheme is simple, can drive branch liquid mechanism rotatory when the cooling water transports, the cost is reduced, the dismouting is simple, the practicability is improved.

Drawings

Fig. 1 is an internal schematic view of a liquid cooling mechanism of a rotary liquid separator for a liquid cooling cabinet according to the present invention;

fig. 2 is a front view of a liquid separating mechanism of a rotary liquid separator for a liquid cooling cabinet according to the present invention;

fig. 3 is a front structural sectional view of a liquid separating mechanism of a rotary liquid separator for a liquid cooling cabinet according to the present invention;

fig. 4 is an enlarged view of the rotary liquid distributor for a liquid-cooled cabinet of the present invention at a point a in fig. 3;

fig. 5 is a top view structural cross-sectional view of a liquid separating housing of a rotary liquid separator for a liquid cooling cabinet according to the present invention;

fig. 6 is a partial side sectional view of the rotary liquid distributor for a liquid-cooled cabinet of the present invention at B-B in fig. 5;

fig. 7 is a partial front view of a cannula of a rotary dispenser for a liquid-cooled cabinet according to the present invention.

In the figure:

1. a main water supply pipeline;

2. a diversion pipeline;

3. installing a sleeve;

4. a liquid separating mechanism; 41. a liquid separating shell; 411. a push plate; 42. inserting a tube;

43. a waterproof bearing; 44. a mounting member; 45. a limiting rod; 46. pulling the block;

47. an extension pipe; 48. a support frame; 49. an annular groove;

5. an electrically controlled valve;

6. sealing the rubber gasket;

7. an inclined tube;

8. rotating the groove;

9. and (4) a ball.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts all belong to the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "front end", "rear end", "both ends", "one end", "the other end", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted", "provided", "connected", and the like are to be construed broadly, such as "connected", which may be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Referring to fig. 1-7, the present invention provides a technical solution: a rotary liquid separator for a liquid cooling cabinet comprises a main water supply pipeline 1, a plurality of component flow pipelines 2, a plurality of component mounting sleeves 3 and a plurality of component flow mechanisms 4.

The main water supply pipeline 1 is arranged inside the liquid cooling cabinet. The transportation of the cooling liquid can be realized by external water supply equipment such as a high-pressure pump and the like in the main water supply pipeline 1, so that the cooling liquid is conveyed to the inside of the main water supply pipeline 1 and the liquid cooling cabinet.

The plurality of component flow pipelines 2 and the plurality of groups of mounting sleeves 3 are fixedly connected to the top of the main water supply pipeline 1 at equal intervals.

An electric control valve 5 is arranged on the shunt pipe 2. Specifically, the shunt pipeline 2 is communicated with the main water supply pipeline 1, and the pipeline circulation of the shunt pipeline 2 is controlled through an electric control valve 5.

The plurality of component distributing mechanisms 4 are respectively connected to the plurality of component distributing pipelines 2.

The liquid separating mechanism 4 comprises a liquid separating shell 41, an insertion tube 42, a waterproof bearing 43 and a plurality of groups of extension tubes 47, wherein:

the inner top surface of the liquid separation shell 41 is in a regular annular array and is fixedly connected with a plurality of groups of pushing plates 411;

the waterproof bearing 43 is fixedly arranged in the bottom of the liquid separation shell 41 in a penetrating manner;

the insertion tube 42 is fixed in the inner ring of the waterproof bearing 43, and the lower end of the insertion tube 42 is connected into the top of the shunt pipeline 2;

several sets of extension tubes 47 are fixedly connected to the surface of the liquid separation housing 41 in a regular annular array. Specifically, inside extension pipe 47 put through dividing liquid casing 41, extension pipe 47 level set up, and extension pipe 47 keeps away from dividing liquid casing 41 one end and is the enclosed construction, divides liquid casing 41 to be cylindrical shell structure.

Specifically, the waterproof bearing 43 supports the insertion tube 42, and when the insertion tube 42 is fixed, the rotation of the liquid separation housing 41 and the plurality of sets of extension tubes 47 can be realized.

The upper end of the insertion tube 42 is of a C-shaped structure, the outer diameter length of the lower end of the insertion tube 42 is matched with the inner diameter length of the shunt pipeline 2, and the outer side of the lower end of the insertion tube 42 is sleeved with the sealing rubber gasket 6. Specifically, referring to fig. 5 of the specification, the upper end of the insertion tube 42 is viewed as a "C" shaped structure in plan, and referring to fig. 3 of the specification and fig. 6 of the specification, the insertion tube 42 is located below the pushing plate 411 in a horizontal position, the top of the insertion tube 42 is arranged obliquely, the opening at the top of the insertion tube 42 is arranged obliquely upward, the cooling liquid discharged from the opening at the top of the insertion tube 42 is sprayed obliquely upward and hits the surface of the pushing plate 411, and thus the pushing plate 411 and the liquid separation shell 41 are pushed to rotate by the thrust of the water flow.

In particular, the sealing rubber gasket 6 effectively improves the sealing performance of the joint of the insertion tube 42 and the shunt pipeline 2.

The top of the extension pipe 47 is fixedly connected with a plurality of groups of inclined pipes 7 at equal intervals. Specifically, the pipe chute 7 slope sets up, and in the pipe chute 7 switch-on was in extension 47, divides the inside cooling water of liquid casing 41 to transport in a plurality of groups of extension 47, and then spout in following a plurality of groups of pipe chutes 7 to at the in-process that divides liquid casing 41, a plurality of groups of extension 47 and a plurality of groups of pipe chute 7 synchronous rotation, with the even liquid cooling rack that sprays of coolant inside, improve the coverage and the degree of consistency of coolant.

The liquid separating mechanism 4 further comprises a mounting piece 44, a limiting rod 45 and a pulling block 46, wherein:

the lower end of the mounting piece 44 is connected to the inner side of the mounting sleeve 3 in a clearance fit manner;

the limiting rod 45 is inserted and connected in the mounting part 44 and one side of the mounting sleeve 3 in a clearance fit manner;

the pulling block 46 is fixedly connected to one end of the limiting rod 45, and a spring is fixedly connected between the pulling block 46 and the surface of the mounting sleeve 3.

Specifically, refer to specification attached drawing 3, the lower extreme of installed part 44 is cylindrical structure, diameter length and the installation sleeve 3 internal diameter length phase-match of installed part 44 lower extreme, all set up the through-hole that supplies gag lever post 45 to alternate the connection in the installed part 44 lower extreme and the installation sleeve 3, and this two sets of through-holes and gag lever post 45 clearance fit, and the spring has synchronous elastic action to gag lever post 45 and pull piece 46, thereby make the stable connection of gag lever post 45 in installed part 44 and in installation sleeve 3, and then realize the spacing fixed connection between installation sleeve 3 and the installed part 44, and then realize the swift installation to dividing liquid mechanism 4, and break away from the back in the installed part 44 through pulling piece 46 control gag lever post 45, can dismantle to dividing liquid mechanism 4.

The liquid separating mechanism 4 further comprises a plurality of groups of support frames 48 and annular grooves 49, wherein:

an annular groove 49 is opened in the surface of the middle part of the insertion tube 42;

a plurality of groups of support frames 48 are fixedly connected to the bottom of the liquid-separating shell 41 in a regular annular array, a rotary groove 8 is formed in one side of the lower end of each support frame 48, which is close to the insertion tube 42, a ball 9 is rotatably connected in the rotary groove 8, and the ball 9 is movably connected in an annular groove 49.

The diameter length of the ball 9 is larger than the opening width of the rotary groove 8. Specifically, referring to the attached drawing 4 in the specification, the rotary groove 8 has a limiting effect on the balls 9, the balls 9 are in contact with the inner wall of the annular groove 49, and the stability of the liquid separation shell 41 during rotation is effectively improved through the effects of the groups of balls 9 and the groups of support frames 48.

Specifically, the cooling water is delivered by the high-pressure pump to the main water supply pipe 1, the branch pipe 2, the insertion pipe 42, the liquid separation housing 41, and the extension pipe 47 in this order, and the cooling water is ejected from the inclined pipe 7.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims (8)

1. The utility model provides a rotatory knockout for liquid cooling rack which characterized in that: comprises a main water supply pipeline (1), a plurality of groups of branch pipelines (2), a plurality of groups of mounting sleeves (3) and a plurality of groups of liquid separating mechanisms (4);

the main water supply pipeline (1) is arranged inside the liquid cooling cabinet;

the groups of the diversion pipelines (2) and the groups of the mounting sleeves (3) are fixedly connected to the top of the main water supply pipeline (1) at equal intervals;

the plurality of component liquid mechanisms (4) are respectively connected to the plurality of component flow pipelines (2).

2. The rotary liquid dispenser for a liquid cooled cabinet of claim 1, wherein: an electric control valve (5) is arranged on the shunt pipeline (2).

3. The rotary liquid dispenser for a liquid cooled cabinet of claim 1, wherein: divide liquid mechanism (4) including dividing liquid casing (41), intubate (42), waterproof bearing (43) and a plurality of groups extension pipe (47), wherein:

the inner top surface of the liquid-separating shell (41) is in a regular annular array and is fixedly connected with a plurality of groups of pushing plates (411);

the waterproof bearing (43) is fixedly arranged in the bottom of the liquid separation shell (41) in a penetrating manner;

the insertion pipe (42) is fixed in an inner ring of the waterproof bearing (43), and the lower end of the insertion pipe (42) is connected into the top of the shunt pipeline (2);

and a plurality of groups of extension pipes (47) are fixedly connected to the surface of the liquid-separating shell (41) in a regular annular array.

4. The rotary dispenser for a liquid-cooled cabinet of claim 3, wherein: the upper end of intubate (42) is "C" type structure, and the external diameter length of intubate (42) lower extreme matches with the internal diameter length of reposition of redundant personnel pipeline (2), and the lower extreme outside cover of intubate (42) is equipped with sealed cushion (6).

5. The rotary liquid dispenser for a liquid cooled cabinet of claim 3, wherein: the top of the extension pipe (47) is fixedly connected with a plurality of groups of inclined pipes (7) at equal intervals.

6. The rotary liquid dispenser for a liquid cooled cabinet of claim 1, wherein: divide liquid mechanism (4) still include installed part (44), gag lever post (45) and draw piece (46), wherein:

the lower end of the mounting piece (44) is connected to the inner side of the mounting sleeve (3) in a clearance fit manner;

the limiting rod (45) is in clearance fit and penetrating connection in the mounting piece (44) and in one side of the mounting sleeve (3);

draw piece (46) fixed connection in the one end of gag lever post (45), and draw fixedly connected with spring between piece (46) and installation sleeve (3) surface.

7. The rotary dispenser for a liquid-cooled cabinet of claim 3, wherein: divide liquid mechanism (4) still include a plurality of groups support frame (48) and ring channel (49), wherein:

the annular groove (49) is formed in the surface of the middle part of the insertion pipe (42);

the support frames (48) are fixedly connected to the bottom of the liquid separating shell (41) in a regular annular array mode, a rotary groove (8) is formed in one side, close to the insertion pipe (42), of the lower end of each support frame (48), the rotary groove (8) is connected with a ball (9) in a rotating mode, and the ball (9) is movably connected into the annular groove (49).

8. The rotary dispenser for a liquid-cooled cabinet of claim 7, wherein: the diameter length of the ball (9) is larger than the opening width of the rotary groove (8).

Images