CN210640476U

CN210640476U - Water diversion module and laser

Info

Publication number: CN210640476U
Application number: CN201921010405.8U
Authority: CN
Inventors: 杨德权; 雷喜良; 蒋峰
Original assignee: Maxphotonics Co Ltd; Suzhou Maxphotonics Co Ltd
Current assignee: Maxphotonics Co Ltd; Suzhou Maxphotonics Co Ltd
Priority date: 2019-07-01
Filing date: 2019-07-01
Publication date: 2020-05-29
Anticipated expiration: 2029-07-01

Abstract

The utility model discloses a water diversion module and a laser, wherein, the water diversion module comprises a main branch water diversion block and a plurality of branch adapters, two ends of the main branch water diversion block are communicated, one end of the main branch water diversion block is a water inlet and outlet end for water inlet and outlet, the other end is a sealing end, and a plurality of water inlet and outlet holes are arranged on the main branch water diversion block; a plurality of branch road adapters correspond respectively and connect a plurality of business turn over water holes, a plurality of branch road adapters are used for connecting a plurality of branch roads, and, include two kinds at least flow channel's branch road adapter in a plurality of branch road adapters. Through the input of different flow, can realize the control to the flow size to reduce the total flow demand, improve refrigeration efficiency.

Description

Water diversion module and laser

Technical Field

The utility model relates to a laser equipment water-cooling field especially relates to a divide water module and laser instrument that is used for different flow control and multiplexed output.

Background

The laser water cooling mainly comprises the steps of carrying out water circulation cooling on a laser generator of the laser equipment, and controlling the service temperature of the laser generator so that the laser generator can keep working normally for a long time. Laser equipment is at long-time operation in-process, and laser generator can constantly produce high temperature, and the normal work that laser generator will be influenced to the high temperature, so need carry out water circulative cooling accuse temperature.

The design of the water distribution block is an important link in the water circulation cooling design of the laser equipment, the water distribution block divides main path inlet water into multiple paths to be output to different photoelectric modules, and flow and water pressure distribution is carried out according to heat dissipation requirements, so that the heat dissipation requirements of the modules are met.

At present, a water diversion block commonly used in the laser industry is designed in such a way that an aluminum block is machined, a trunk runner is added through a deep hole drilling machine, and a branch runner is machined on the side surface. Not only the processing is relatively difficult, the processing cost is high, but also the output of different flow rates can not be realized.

Disclosure of Invention

The embodiment of the utility model provides a divide water module and laser instrument utilizes the branch road adapter of two kinds of at least flow channel who is connected with a plurality of business turn over water holes, can realize different flow input and output.

In view of this, the embodiment of the utility model provides a first aspect provides a divide water module, include:

the main path water distribution block is communicated with two ends, one end of the main path water distribution block is a water inlet end and a water outlet end for water inlet and outlet, the other end of the main path water distribution block is a sealing end, and a plurality of water inlet and outlet holes are formed in the main path water distribution block;

a plurality of branch road adapters, a plurality of branch road adapters correspond respectively and are connected a plurality of business turn over water holes, a plurality of branch road adapters are used for connecting a plurality of branch roads, and, include two kinds at least flow channel's branch road adapter in a plurality of branch road adapters.

Further, the water diversion module comprises a plurality of branches connected with the module to be cooled, and the plurality of branches comprise: a plurality of flexible hoses;

the two ends of the flexible hoses are connected to the branch adapters and the positions between the branch adapters and the modules to be cooled respectively to form the branch connectors.

Further, the water diversion module further comprises:

the main road adapter is connected to the water inlet and outlet end of the main road water diversion block and is used for water inlet and outlet of the main road water diversion block;

the sealing cover is used for sealing and fixing the sealing end of the main path water pipe;

the shell is used for installing the main path water distribution block and is fixedly connected with the module to be cooled.

Further, the main path water diversion block comprises a water inlet water diversion block and a water outlet water diversion block;

the plurality of water inlet and outlet holes comprise a plurality of water inlet holes and a plurality of water outlet holes;

the branch adapters comprise a plurality of input adapters and a plurality of output adapters;

the water inlet holes are formed in the water inlet water distribution block, and the water outlet holes are formed in the water outlet water distribution block;

the plurality of water inlets are respectively and correspondingly connected with the plurality of input adapters, and the plurality of water outlets are respectively and correspondingly connected with the plurality of output adapters.

Further, the branch adapter of at least two kinds of flow channel is including setting up the branch adapter of two kinds of internal diameters at least, the branch adapter of two kinds of at least gaskets or the branch adapter of two kinds of at least ball valves at least.

Further, the water inlet water distribution block and the water outlet water distribution block in the water distribution module are arranged in the shell side by side;

and the water inlet water distribution block and the water outlet water distribution block are perpendicular to the module to be cooled.

Furthermore, in the water inlet water distribution block and the water outlet water distribution block, the opening directions of the water inlet holes are perpendicular to the opening directions of the water outlet holes.

Further, the water diversion module further comprises: the bending adapters are used for connecting the input adapters or the output adapters so that the water inlet direction of the water inlet water distribution block is parallel to the water outlet direction of the water outlet water distribution block;

the plurality of bent adapters comprise a folding adapter and a plurality of folding adapters.

Furthermore, in the water inlet and outlet water distribution blocks, the plurality of water inlets are arranged in a staggered manner relative to the plurality of water outlets.

Further, the misalignment setting includes: the water inlet holes and the water outlet holes are arranged at intervals.

Furthermore, the water inlet and outlet blocks are in a pipeline shape, and the cross sections of the water inlet and outlet blocks are circular, square, rectangular or triangular.

A second aspect of the embodiments of the present invention provides a laser, including as in the first aspect above the water diversion module and with the module of treating heat dissipation that the water diversion module is connected.

Furthermore, the laser comprises a shell, wherein a mounting cavity is formed in the shell and used for fixing a module to be radiated and a water diversion module, and the module to be radiated is fixed on the side surface of the mounting cavity; the water distribution module is arranged at the bottom of the installation cavity, and the water inlet water distribution block and the water outlet water distribution block are arranged perpendicular to the module to be cooled;

the water diversion module comprises a water inlet diversion block and a water outlet diversion block which are arranged side by side, a plurality of water inlet holes are formed in the water inlet diversion block, and a plurality of water outlet holes are formed in the water outlet diversion block;

the plurality of water inlet holes are correspondingly connected with a plurality of input adapters, the plurality of water outlet holes are correspondingly connected with a plurality of output adapters, and the plurality of input adapters comprise input adapters of at least two flow channels;

the plurality of input adapters and the plurality of output adapters are respectively connected with the module to be cooled through flexible hoses.

According to the technical solution provided by the utility model, the embodiment of the utility model has the following advantage:

through a plurality of inlet openings that set up on main road water diversion piece to and correspond a plurality of branch adapter of connecting these a plurality of inlet openings, utilize the branch adapter of two kind at least flow channels that set up in these a plurality of branch adapters, can realize the input of different flows, thereby reach the control flow size, reduce the total flow demand, improve refrigeration efficiency's purpose.

Drawings

In order to more clearly illustrate embodiments of the present invention or solutions in the prior art, one or more embodiments are exemplarily described below with reference to the accompanying drawings, which do not constitute a limitation of the embodiments, wherein elements having the same reference numerals are denoted by similar elements, unless otherwise specified, and the drawings are not to scale.

Fig. 1 is a schematic diagram of an embodiment of a laser with a water diversion module according to an embodiment of the present invention;

FIG. 2 is a schematic view of the water inlet and distribution block in the embodiment of the present invention;

FIG. 3 is a schematic diagram of the square water inlet and distribution block in the embodiment of the present invention;

fig. 4 is a schematic structural diagram of an input adapter in an embodiment of the present invention;

fig. 5 is a schematic view of the bending adapter structure in the embodiment of the present invention.

Description of reference numerals:

the water distribution module-100, the main road water distribution block-10, the branch adapters-20, the main road adapter-30, the internal tooth adapter-40, the shell-50, the flexible hose-60, the bending adapter-70 and the sealing cover-80;

the water inlet water distributing block-11, the water outlet water distributing block-12, the input adapter-21, the output adapter-22, the connecting end-71, the bending end-72 and the connecting pipe-73;

a water inlet hole-111;

the module to be radiated comprises-200 parts of a module to be radiated, 210 parts of a radiating water inlet and 220 parts of a radiating water outlet.

Detailed Description

In order to facilitate understanding of the present invention, the present invention will be described in more detail with reference to the accompanying drawings and specific embodiments. It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may be present. The terms "vertical," "horizontal," "side," "bottom," "inner," "outer," "axial," and the like as used herein are defined as orientations and positional relationships based on the orientation shown in the drawings, and are used for convenience in describing and simplifying the present invention, and do not indicate or imply that the device or element so referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present invention.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention.

The following describes the water diversion module for different flow control and multi-path output in the embodiment of the present invention in detail with reference to the attached drawings.

Referring to fig. 1 to 5, in an embodiment of the water diversion module 100 according to the present invention, the water diversion module 100 includes a main branch water diversion block 10, a plurality of branch adapters 20, a main branch adapter 30, an internal tooth adapter 40, and a sealing cover 80.

Wherein, the two ends of the main path water diversion block 10 are through, one end of the main path water diversion block is a water inlet and outlet end for water inlet and outlet, the other end is a sealing end, the water inlet and outlet end can be connected with a main path adapter 30 and an internal tooth adapter 40 in a matching way, the sealing end can be connected with a sealing cover 80 in a sealing way, and the main path adapter 30 can be used for water inlet or water outlet of a main path formed by the main path water diversion block 10.

And a plurality of water inlet and outlet holes may be provided on the main path water diversion block 10. These a plurality of business turn over water holes correspond respectively and connect a plurality of branch road adapter 20, and a plurality of branch roads are connected respectively to these a plurality of branch road adapter 20, and it can be used to the intaking or the play water of a plurality of branch roads.

The branch adapters 20 include at least two types of branch adapters for flow paths.

Specifically, as shown in fig. 1, the water diversion module 100 may be installed in a laser and may be connected to a module 200 to be cooled of the laser. It should be understood that the laser may include a housing 50, and a mounting cavity may be constructed in the housing 50, which may be used to secure the module to be cooled 200 and the module to be cooled 100. In the laser, the module to be cooled 200 may be fixed to the side of the mounting cavity of the housing 50, and the water diversion module 100 may be mounted at the bottom of the mounting cavity of the housing 50.

In addition, in the installation cavity of the housing 50, a plurality of flexible hoses 60 may be connected between a plurality of branch adapters 20 disposed on the main water diversion block 10 in the water diversion module 100 and the module to be cooled 200, so as to form a plurality of branches. The plurality of branches may be used to divert the cooling fluid in the main path formed by the main path water diversion block 10.

The main path water diversion block 10 may include a water inlet water diversion block 11 and a water outlet water diversion block 12, and the water inlet water diversion block 11 and the water outlet water diversion block 12 are respectively connected with the module to be cooled 200 through flexible hoses 60. The water inlet and outlet blocks 11 and 12 are used for inputting and outputting cooling fluid to form a cooling loop. To achieve a simple installation inside the housing 50, the inlet water diversion block 11 and the outlet water diversion block 12 can be installed side by side inside the housing 50, for example: may be mounted horizontally side-by-side at the bottom of the mounting cavity in the housing 50.

Referring to fig. 1 and fig. 2, a plurality of water inlets 111 may be disposed on the water inlet water diversion block 11, and a plurality of water outlets (not shown in the drawings) may be disposed on the water outlet water diversion block 12, it should be noted that the water outlet water diversion block 12 and the water inlet water diversion block 11 have the same composition structure, and for avoiding repeated descriptions, the water inlet water diversion block 11 is described as an example in this embodiment, and the structure of the water outlet water diversion block 12 may refer to the water inlet water diversion block 11.

As shown in fig. 2, the water inlet block 11 is a hollow stainless steel pipe, and a plurality of water inlets 111 are drilled on the hollow stainless steel pipe, and the drilled water inlets 111 can be pre-drilled according to the heat dissipation requirement or the position corresponding to the module 200 to be heat dissipated. Or, the water inlet water diversion block 11 is drilled with water inlet holes 111 which are uniformly distributed, and the module to be cooled 200 can be connected as required when in use.

A sealing cover 80 may be provided at the end of the water inlet block 11, i.e., at the cutting cut of the stainless steel pipe, and the material of the sealing cover 80 is not limited to plastic, rubber or metal.

The water inlet and outlet water-dividing

blocks

11 and 12 may be square pipes as shown in fig. 3.

The water inlet and outlet blocks 11 and 12 may be made of stainless steel, aluminum pipe, copper pipe, or other materials, and the cross-sectional shape includes, but is not limited to, circular, square, rectangular, or triangular. For example, a square tube as shown in fig. 3.

As shown in fig. 3, a main adapter 30 and an internal adapter 40 that are mutually matched may be installed at a water inlet end of the water inlet diversion block 11, the main adapter 30 is mainly used to connect an external pipeline (not shown in the figure), and the internal adapter 40 is connected to the water inlet diversion block 11, that is, the water inlet diversion block 11, the internal adapter 40 and the main adapter 30 are tightly connected by the matching of internal and external threads. This type of interior tooth adapter 40 and main road adapter 30 includes but not limited to straight tube or taper pipe, the embodiment of the utility model provides a preferentially adopt RC threaded adapter, RC promptly sealed circular cone internal thread characteristic code number of english system.

The water outlet end of the water outlet block 12 may also be provided with the above-mentioned internal adapter 40 and main adapter 30.

In this embodiment, in order to facilitate the connection between the water inlet and outlet blocks 11 and 12 and the module 200 to be cooled, a plurality of input adapters 21 may be respectively and correspondingly connected to the plurality of water inlets 111 in the water inlet and outlet block 11; in the water outlet block 12, a plurality of water outlet holes may be respectively and correspondingly connected with a plurality of output adapters 22.

The input adapter 21 and the output adapter 22 can be shown in fig. 4, and can be inserted into the water inlet 111 or the water outlet through a narrow-end card a, for example: an input adapter is inserted into each water inlet 111, and an output adapter is inserted into each water outlet. The wide-mouth ends B of the input adapter 21 and the output adapter 22 may then be connected to the module to be heat dissipated 200 by the flexible hose 60.

As shown in fig. 1, the module 200 to be dissipated may be connected to a side surface of the housing 50, the main path water diversion block 10 is disposed at the bottom of the mounting cavity, and a blank interval may be formed between the module 200 to be dissipated at the side surface and the main path water diversion block 10 at the bottom, that is, a blank interval may exist above the main path water diversion block 10. It is understood that the water pipe connecting the module to be heat-dissipated 200 and the main water diversion block 10 can be arranged in the empty space, and the water pipe can be a flexible hose 60 made of flexible material for facilitating the installation and connection. The flexible hose 60 includes, but is not limited to, a plastic hose, a rubber hose, a metal mesh hose, and the like.

Specifically, the water diversion module 100 in the embodiment of the present invention may be integrated with the laser device, that is, the housing 50 may be integrated with the housing of the laser device; the water diversion module 100 may also be externally installed as a separate body, and the water diversion module 100 may be installed at the module 200 to be heat-dissipated of the laser device, that is, the side surface of the housing 50 is connected to the laser device, and the side surface is aligned to the module 200 to be heat-dissipated. It should be understood that the side of the housing 50 facing the module 200 to be heat-dissipated of the laser device may be reserved with a matching opening for connecting the module 200 to be heat-dissipated with the main water diversion block 10 disposed at the bottom inside the housing 50.

In this case 50, the main path water diversion block 10 may be installed horizontally with respect to the module to be heat-dissipated 200 to simplify the space. It should be understood that the module 200 to be heat-dissipated in the laser device may be an optical module or an electrical module, and the number of the optical modules or the electrical modules may be increased according to the requirement of the processing technology. Therefore, the module to be heat dissipated 200 can be stacked in plurality, for example, in a horizontal direction, the main path water diversion block 10 can extend along the direction in which the modules to be heat dissipated 200 are horizontally stacked.

Meanwhile, in order to change the difficulty of the existing processing, the main path water diversion block 10 can be replaced by a hollow stainless steel pipe, and the processing is simple and is not limited by deep hole processing. The required length can be correspondingly intercepted according to the number of the modules 200 to be radiated during design.

As shown in fig. 1, three pairs of heat dissipation water inlets 210 and heat dissipation water outlets 220 may be provided in the module to be heat dissipated 200, and the number of the three pairs is illustrated in fig. 1, but it may be an integer pair other than the three pairs. The heat dissipation water inlet 210 may be disposed at the lower end of the module to be dissipated 200, or at the upper end thereof; the heat dissipation water outlet 220 may be disposed at the upper end of the module to be dissipated 200, or at the lower end thereof; specifically depend on the design requirement of the module 200 to be cooled, but it should be noted that, the embodiment of the present invention preferably sets the cooling water inlet 210 and the cooling water outlet 220 of the module 200 to be cooled on the same side with the water inlet 111 of the water inlet block 11 and the water outlet of the water outlet block 12.

Preferably, the heat emission outlet 220 may be disposed at an upper end of the module to be heat emitted 200 to prevent the cooling fluid from flowing out, so as to prevent the module to be heat emitted 200 from being overheated.

The heat dissipation water inlet 210 is connected with an input adapter 21 arranged on the water inlet water diversion block 11 through a flexible hose 60, and the heat dissipation water outlet 220 is connected with an output adapter 22 arranged on the water outlet water diversion block 12. Accordingly, it can be understood that the number of the water inlet holes 111 in the water inlet water-splitting block 11 may be greater than or equal to the number of the heat dissipation water inlets 210, and the number of the water outlet holes in the water outlet water-splitting block 12 may be greater than or equal to the number of the heat dissipation water outlets 220.

But the arrangement of the flexible hoses 60 connected between each pair of the water inlet holes 111 and the heat radiating water inlet 210 and each pair of the water outlet holes and the heat radiating water outlet 220 is convenient. In the inlet water-dividing block 11 and the outlet water-dividing block 12 which are arranged side by side, the plurality of inlet holes 111 may be arranged in a staggered manner with respect to the plurality of outlet holes. For example, in a preferred embodiment, the inlet openings 111 are spaced apart from the outlet openings, e.g., one inlet opening 111 is followed by one inlet opening 111, and so on.

It should be noted that the arrangement manner (such as arrangement position, arrangement gap, arrangement number, etc.) of the water inlet holes 111 or the water outlet holes on the water inlet water diversion block 11 or the water outlet water diversion block 12 is adjusted according to the specific heat dissipation requirement, the position of the module 200 to be heat dissipated, etc. during design, or during installation, holes are drilled according to the requirement, which is not limited to the arrangement manner in the description embodiment and the drawings.

In order to further facilitate the connection of the flexible hose 60 and keep the hose running neat and orderly, the opening direction of the water inlet holes 111 in the water inlet water diversion block 11 and the opening direction of the water outlet holes in the water outlet water diversion block 12 can be set vertically as shown in the embodiment of fig. 1. In the water inlet 111 with the opening direction perpendicular to the water outlet, the input adapter 21 fixed in the water inlet 111 can be connected through a plurality of preset bent adapters 70, and the water inlet direction of the water inlet water diversion block 11 is guided to be parallel to the water outlet direction of the water outlet water diversion block 12.

As shown in fig. 5, the connection end 71 of the bending adapter 70 at one end may be fixed to the input adapter 21 by a screw, and an internal thread may be correspondingly provided in the through hole of the input adapter 21. The other end of the bent end 72 may be bent at 90 ° to the connection end 71, and a connection pipe 73 may extend from the bent end 72. The extended connection pipe 73 may be inserted into the flexible hose 60, and the connection fixing may be performed by a contraction force of the flexible hose 60.

It is understood that a plurality of layers of annular grooves may be formed on the connection pipe 73 to enhance the fixing force of the connection flexible hose 60.

The material of the bent adapter 70 is not limited in this embodiment. Also, the folding adapter 70 may comprise a folding adapter as shown in fig. 5, or may comprise a multi-folding adapter. The multi-folding adapter can be in a three-dimensional Z shape, and one end of the multi-folding adapter is perpendicular to the L-shaped bottom. Through this Z type adapter, can conveniently connect flexible hose 60 between the clearance of two inlet openings 111, or connect between the clearance of inlet opening 111 and apopore, do not restrict here specifically.

In the embodiment shown in fig. 1, the output adapters 22 may also be connected to vertical adapters respectively, the bottom of the vertical adapter may also be connected to the output adapter 22 through a screw thread, and a vertical connecting pipe may also extend from the top of the vertical adapter, and the flexible hose 60 may be fixedly connected to the vertical connecting pipe.

In a preferred embodiment, the input adapters 21 include two or more flow channels of the input adapter 21. Specifically, the input adapter 21 may be provided with at least two inner diameters, for example, in the input adapter 21 shown in fig. 4, the difference between the inner diameters of the narrow-mouth end a and the wide-mouth end B is changed to realize different inner diameters. Or the gasket or the ball valve inside the input adapter 21 may be arranged, the input adapter 21 with at least two kinds of gaskets or the input adapter 21 with at least two kinds of ball valves may be arranged, and different flow channels of the input adapter 21 may be realized.

It will be appreciated that the larger inner diameter of the input adapter 21, which also has a larger flow path, allows more cooling fluid to flow per unit time, and thus dissipates heat more quickly. Conversely, the input adapter 21 with a small inner diameter dissipates heat relatively slowly.

The embodiment of the present invention is described with the input adapter 21 with different inner diameters as an example. For example, an input adapter 21 having a large inner diameter is provided on the right side of the inlet manifold block 11, and an input adapter 21 having a small inner diameter is provided on the left side, as shown in fig. 1. The user can select the input adapter 21 with the large inner diameter from the module 200 to be radiated with large calorific value and select the input adapter 21 with the small inner diameter from the module 200 to be radiated with small calorific value through software simulation according to different radiating requirements of different modules 200 to be radiated. Therefore, the accurate utilization of the flow can be realized, the total flow demand of the cooling fluid is reduced, and the aim of improving the refrigeration efficiency is fulfilled.

It will be appreciated that the plurality of output adapters 22 may also include input adapters for at least two flow paths.

In an alternative embodiment, the positions of the water inlet water diversion block 11 and the water outlet water diversion block 12 can also be interchanged, the water outlet water diversion block 12 is arranged on the outer side, and the water inlet water diversion block 11 is arranged on the inner side, referring to the orientation shown in fig. 1, and detailed description thereof is omitted.

In the embodiment of the utility model provides an in, through the different processing mode of change with prior art, adopt stainless steel pipe preparation main road to divide water piece 10, its processing technology is more simple, and does not receive the limitation that the deep hole changes, and length can support more branch road outputs according to the heat dissipation demand setting. By arranging the water inlet and outlet water distribution blocks 11 and 12 at the bottom of the shell 50 side by side, a plurality of water inlet holes 111 are arranged on the water inlet water distribution block 11 in advance, and a plurality of water outlet holes are arranged on the water outlet water distribution block 12 in advance; and, correspond a plurality of input adapter 21 of being connected with these a plurality of inlet openings 111, correspond a plurality of output adapter 22 of being connected with these a plurality of apopores, this a plurality of input adapter 21 and a plurality of output adapter 22 are connected respectively through flexible hose 60 and are treated heat dissipation module 200, can realize that the rule of input adapter 21 and output adapter 22 distributes, flexible hose 60 walks the pipe neatly orderly.

The plurality of input adapters 21 include input adapters 21 for at least two types of flow channels. The input of the different flows of the module to be radiated 200 can be realized by adjusting the arrangement of the input adapters 21 with different inner diameters, so that the control of the flow is achieved, the requirement of the total flow is reduced, and the refrigeration efficiency is improved.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above are not necessarily intended to refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, various embodiments or examples and features of different embodiments or examples described in this specification can be combined and combined by one skilled in the art without contradiction.

The above only is the preferred embodiment of the present invention, not limiting the scope of the present invention, all the equivalent structure changes made by the contents of the specification and the drawings under the inventive concept of the present invention, or the direct/indirect application in other related technical fields are included in the patent protection scope of the present invention.

Claims

1. A water diversion module, comprising:

2. The water diversion module of claim 1, comprising said plurality of branches connecting modules to be heat dissipated, said plurality of branches comprising: a plurality of flexible hoses;

3. The water diversion module of claim 2, further comprising:

4. The water diversion module of claim 3, wherein said main path water diversion block comprises an inlet water diversion block and an outlet water diversion block;

5. The water diversion module of claim 4 wherein said at least two flow passage branch adapters comprise a branch adapter providing at least two inner diameters, a branch adapter providing at least two shims, or a branch adapter providing at least two ball valves.

6. The water diversion module of claim 5 wherein said inlet water diversion block and said outlet water diversion block are mounted side-by-side within said housing;

7. The water diversion module of claim 6, wherein the opening direction of the plurality of water inlet holes is perpendicular to the opening direction of the plurality of water outlet holes in the water inlet block and the water outlet block; in the water inlet water distribution block and the water outlet water distribution block, the plurality of water inlet holes are arranged in a staggered mode relative to the plurality of water outlet holes.

8. The water diversion module of claim 7, further comprising: the bending adapters are used for connecting the input adapters or the output adapters so that the water inlet direction of the water inlet water distribution block is parallel to the water outlet direction of the water outlet water distribution block;

9. A laser comprising the water diversion module of any one of claims 1-8 and a module to be cooled connected to the water diversion module.

10. The laser device as claimed in claim 9, wherein the laser device comprises a housing, a mounting cavity is formed in the housing for fixing a module to be cooled and a water diversion module, and the module to be cooled is fixed on the side surface of the mounting cavity; the water distribution module is arranged at the bottom of the installation cavity, and the water inlet water distribution block and the water outlet water distribution block are arranged perpendicular to the module to be cooled;