CN-122006946-A - Atomizing liquid cooling device

Abstract

The application relates to the technical field of atomizing equipment, and particularly discloses an atomizing liquid cooling device which comprises a liquid supply assembly and a nozzle mounting module, wherein the liquid supply assembly comprises a plurality of liquid supply short pipes which are linearly distributed and are arranged at intervals, the end parts of the liquid supply short pipes are adjacently arranged, a mounting gap is reserved between two adjacent liquid supply short pipes, the nozzle mounting module comprises a nozzle seat which is in a pipe shape and is sleeved at the mounting gap of the two adjacent liquid supply short pipes, a first threaded hole penetrates through the circumferential outer wall of a sleeve mechanism and is close to the mounting gap, and one end of a nozzle is in threaded connection with the first threaded hole. The device is convenient to install, fast to assemble and disassemble, and the pipeline is flexible to splice.

Inventors

• LI YALUN
• SONG ZHIMING
• ZHANG YAO

Assignees

• 东莞市长原喷雾技术有限公司

Dates

Publication Date

20260512

Application Date

20260401

Claims (9)

1. 1. An atomizing liquid cooling device is characterized by comprising a liquid supply assembly (100) and a nozzle mounting module (200), wherein The liquid supply assembly (100) comprises: a plurality of liquid supply short pipes (110) which are linearly distributed and are arranged at intervals, wherein The end parts of the liquid supply short pipes (110) are adjacently arranged, and an installation gap (120) is arranged between two adjacent liquid supply short pipes (110); The nozzle mounting module (200) includes: A nozzle holder (210) which is in a tube shape and is sleeved at the installation gap (120) between two adjacent liquid supply short tubes (110), and A first threaded bore (220) extending through the peripheral outer wall of the bushing mechanism and proximate the mounting gap (120); and one end of the nozzle (300) is in threaded connection with the first threaded hole (220).
2. 2. The atomizing liquid cooling device according to claim 1, wherein said nozzle holder (210) comprises: The pipe-shaped body (211) is sleeved at the installation gap (120), and two ends of the pipe-shaped body extend to the outer walls of the two adjacent liquid supply short pipes (110); The two groups of thickening rings (212) are arranged, and the two groups of thickening rings (212) are respectively arranged at two ends of the tubular body (211) and are coaxially sleeved on the circumferential outer wall of the tubular body (211); the second threaded holes (213) are formed in a plurality, the second threaded holes (213) are annularly distributed at intervals at the two thickening rings (212), and the annularly distributed second threaded holes (213) are coaxially arranged on the thickening rings (212); Each second threaded hole (213) penetrates through the outer wall of the tubular body (211) and points to the outer wall of the liquid supply short pipe (110); and the locking screw (214) is in threaded connection with each second threaded hole (213), and one end of the locking screw passes through the second threaded holes (213) to be abutted with the outer wall of the liquid supply short pipe (110).
3. 3. The atomizing liquid cooling device according to claim 2, wherein said nozzle mounting module (200) further comprises: A seal assembly (230), the seal assembly (230) comprising: a limiting ring (231) provided with two groups and arranged on the inner wall of the tubular body (211) at intervals and coaxially arranged with the tubular body (211), wherein The limiting rings (231) are arranged at two sides of the installation gap (120); The sealing rings (232) are provided with two groups and are arranged between the two groups of limiting rings (231); An annular protrusion (233) coaxially provided on the inner wall of the tubular body (211); The annular bulge (233) is arranged between the two groups of sealing rings (232), and the end walls at the two ends of the annular bulge (233) are abutted against the end walls of two adjacent liquid supply short pipes (110), wherein The first threaded hole (220) penetrates through the annular protrusion (233) and is communicated with the inner flow passage of the liquid supply short pipe (110).
4. 4. An atomizing liquid cooling device according to claim 3, wherein said liquid supply assembly (100) further comprises: a housing assembly (130), the housing assembly (130) comprising: a protective shell with a C-shaped section and a cover plate (134) with a U-shaped section are spliced to form the protective shell, wherein The protective housing includes: A housing (131) having a C-shaped cross section and a flat cross section at the bottom; The brackets (132) are symmetrically arranged along the axis of the shell (131), and a plurality of the brackets (132) are linearly distributed along the axis of the shell (131); One end of the bracket (132) is connected with the inner wall of the shell (131), the other end of the bracket points to the outer wall of the liquid supply short pipe (110), and one end, which is close to the outer wall of the liquid supply short pipe (110), is provided with a V-shaped clamping jaw (133).
5. 5. The atomizing liquid cooling device according to claim 4, wherein a plurality of nozzle mounting holes (135) are provided at intervals along a length direction of said cover plate (134), said nozzle mounting holes (135) being provided through a surface of said cover plate (134), wherein An end of the nozzle (300) remote from the first threaded bore (220) is disposed through the nozzle mounting bore (135).
6. 6. The atomizing liquid cooling device according to claim 5, wherein said nozzle (300) comprises a second base (310) having one end threadedly coupled to said first threaded bore (220), wherein A liquid inlet hole (310 a) is formed in the axis of the second base (310), and the liquid inlet hole (310 a) is communicated with the liquid supply short pipe (110); A filter cotton (320) arranged at the end part of the liquid inlet hole (310 a) in the second base (310); the first base (330) is arranged at one end of the second base (310) far away from the liquid supply short pipe (110) and is in threaded connection with the second base (310); An atomization cavity (330 a) is arranged in the first base (330), and the atomization cavity (330 a) is communicated with the liquid inlet hole (310 a); the plug (340) is arranged at one end of the atomizing cavity (330 a) close to the filter cotton (320); a swirl core (350) which is arranged in the atomization cavity (330 a) and one end of which is close to the plug (340); The spring (360) is sleeved on the circumferential outer wall of the cyclone core (350), and one end of the spring is abutted against the plug (340); a cap (370) threadably coupled to an end of the first base (330) remote from the second base (310); the end wall of the cap (370) is provided with a mist outlet (370 a), and the mist outlet (370 a) is communicated with the atomization cavity (330 a); a ceramic insert (380) arranged on one surface of the cap (370) close to the first base (330) and arranged at the mist outlet (370 a); Rubber rings (390) are arranged between the cap (370) and the first base (330), between the first base (330) and the second base (310) and between the second base (310) and the first threaded hole (220).
7. 7. The atomizing liquid cooling device according to claim 6, wherein a microchannel heat exchange assembly (400) is further provided in the liquid supply short tube (110), the microchannel heat exchange assembly (400) comprising: The reducer pipe assemblies (410) are arranged in a plurality, the reducer pipe assemblies (410) are arranged at intervals along the inner wall of the liquid supply short pipe (110), and the extending direction of the reducer pipe assemblies (410) is coaxial with the liquid supply short pipe (110); Mounting rings (420) which are provided with two groups at intervals and are respectively arranged at two ends of the liquid supply short pipe (110), wherein Both ends of each reducer pipe assembly (410) are respectively arranged on the mounting ring (420) and extend out of the end wall of the mounting ring (420).
8. 8. The atomizing liquid cooling device of claim 7, wherein said reducer pipe assembly (410) comprises: A first pipeline (411), a second pipeline (412), and a third pipeline (413), wherein The first pipeline (411) and the third pipeline (413) are respectively arranged at two ends of the second pipeline (412), and the first pipeline (411) and the third pipeline (413) are respectively communicated with two ends of the third pipeline (413); -the diameter of the first conduit (411) and the third conduit (413) is smaller than the diameter of the second conduit (412); the junction of the first pipe (411) and the third pipe (413) with the second pipe (412) is smoothly transited.
9. 9. The atomized liquid cooling device according to claim 8, wherein a first sleeve (414) and a second sleeve (415) are respectively arranged at one end of the first pipeline (411) and one end of the third pipeline (413) far away from the second pipeline (412), and the second sleeve (415) is used for being embedded into the inner wall of the first sleeve (414) adjacent to the liquid supply short pipe (110).

Description

Atomizing liquid cooling device Technical Field The application relates to the technical field of atomization equipment, in particular to an atomization liquid cooling device. Background The atomized liquid cooling device is widely applied to heat dissipation scenes of core heating components such as common spray cooling, spray dust fall, server CPU/GPU and the like due to the characteristic of atomized spraying, and the convenience of installation and maintenance directly influences the use efficiency and the operation and maintenance cost. In the structural design of the existing atomization liquid cooling device, the connection mode of a liquid supply assembly and a nozzle is a key link affecting the convenience of disassembly and assembly. At present, the liquid supply pipeline is commonly adopted in the industry and the nozzle is matched with the connecting structure of the buckle through the quick-screwing connector, when the structure is installed each time, the quick-screwing connector is required to be abutted and then locked and fixed through the special buckle, the buckle is required to be dismantled firstly to separate the connector when the structure is disassembled, the operation steps of the whole process are complex, the buckle belongs to a fragile accessory, and the buckle is required to be frequently replaced after being disassembled and assembled for many times, so that the maintenance cost and the operation difficulty are further increased. Meanwhile, the liquid supply pipelines are in integral design or sectional type fixed connection, and the lack of an adaptive installation positioning structure between the adjacent liquid supply pipelines leads to insufficient positioning precision during pipeline splicing, so that the installation accuracy of the nozzles is affected, and the complexity of the disassembly and assembly process is further increased. In practical application scenes, whether the daily maintenance of a server heat radiation system, the outdoor operation adjustment of spray dust settling equipment or the mobile deployment of a cooling device, the atomized liquid cooling device needs to be frequently disassembled and assembled or the pipelines are spliced. The problem of complicated disassembly and assembly of the traditional structure is that operators consume a great deal of time to finish the installation, maintenance and adjustment of equipment, the operation efficiency is obviously reduced, and for long-distance or multi-nozzle application scenes, frequent fastener disassembly and assembly and pipeline positioning adjustment can greatly increase the labor intensity, and even the joint sealing failure is possibly caused by improper disassembly and assembly, so that the normal operation of the device is affected. Therefore, the problems of inconvenient loading and unloading, poor flexibility of pipeline splicing and the like in the existing atomization liquid cooling device become key pain points for restricting the use experience and the application efficiency. Therefore, a solution that can simplify the assembly and disassembly process and improve the assembly flexibility is needed. Disclosure of Invention The embodiment of the application solves the problems of complicated disassembly and assembly of the liquid supply assembly and the nozzle and poor flexibility of pipeline splicing in the prior art by providing the atomization liquid cooling device, and achieves the effects of convenient installation, quick disassembly and flexible pipeline splicing. The embodiment of the invention provides an atomization liquid cooling device which comprises a liquid supply assembly and a nozzle installation module, wherein the liquid supply assembly comprises a plurality of liquid supply short pipes which are linearly distributed and are arranged at intervals, the end parts of the liquid supply short pipes are adjacently arranged, an installation gap is formed between two adjacent liquid supply short pipes, the nozzle installation module comprises a nozzle seat which is in a pipe shape and is sleeved at the installation gap of two adjacent liquid supply short pipes, a first threaded hole penetrates through the circumferential outer wall of a sleeve mechanism and is close to the installation gap, and one end of a nozzle is in threaded connection with the first threaded hole. In one possible implementation mode, the nozzle holder comprises a tubular body, two thickening rings, a plurality of second threaded holes, second threaded holes and locking screws, wherein the tubular body is sleeved at the mounting gap, two ends of the thickening rings extend to the outer walls of two adjacent liquid supply short pipes, the two thickening rings are respectively arranged at two ends of the tubular body and coaxially sleeved on the circumferential outer walls of the tubular body, the second threaded holes are annularly distributed at the two thickening rings at intervals and are coaxially arran