TWM573931U - Liquid transfer module and liquid cooling system thereof - Google Patents

Abstract

A liquid transfer module is applied to a liquid cooling system, the liquid transfer module includes: a first conductive fluid and a second conductive fluid are removable by a liquid storage tank and a pump unit, the pump The unit includes at least one pump, and the first and second fluid guides are provided with a plurality of flow passages, and the partial flow passages are respectively connected to each other through a check valve, and the other flow passages are communicated through the through holes, and an inlet and an outlet respectively respectively Communicating with different flow paths to allow a working liquid to flow into the liquid transport module, and the working liquid is guided to flow through the liquid storage tank and the pump unit via the liquid transport module, and is removed in the liquid storage tank The working fluid is maintained in the liquid cooling system while the at least one pump of the pump unit is being removed.

Description

Liquid transfer module and liquid cooling system thereof

A liquid transport module and a liquid cooling system thereof, especially a liquid transport module that maintains an uninterrupted operation of a liquid cooling system.

In recent years, liquid cooling systems have been widely used in high-power heat sources for heat dissipation. Because of their better heat dissipation efficiency, they have been widely used in industrial computers or server system cabinets for heat dissipation in addition to personal computer desks. The liquid cooling system is mainly composed of a water-cooling head, a pump, a liquid storage tank and a liquid cold discharge (or a heat-dissipating water discharge). The water-cooling head is used for contacting the heat source and transferring the heat of the heat source to the heat by heat exchange. The working liquid is used to dissipate the working liquid passing through the water-cooling head, and the working liquid is cooled by the liquid to be cooled, and then flows through the liquid storage tank and is pumped. The working fluid circulating in the liquid cooling system is slightly lost over time, and the liquid storage tank is pre-filled with a supplementary working liquid to make up for the lost working liquid. The pump drives the working fluid flow of the liquid cooling system. However, the above units are connected in series by the pipe body, and then the working liquid is cooled and operated. If one of the pump or the liquid storage tank in the liquid cooling system is disabled, the entire liquid cooling system must be stopped. .

One of the aims of the present invention is to provide a liquid transfer module that transfers a working fluid between a liquid storage tank and a pump unit and a water-cooling head and a liquid cold discharge. Another object of the present invention is to provide a liquid transport module that maintains the uninterrupted operation of a liquid cooling system. Another object of the present invention is to provide a method of pumping at least two pumps in a flow path to pressurize a working fluid in a liquid cooling system to increase fluid pressure and flow velocity. Another object of the present invention is to provide a liquid cooling system that does not need to be stopped when the parts are replaced. Another object of the present invention is to provide a liquid cooling system that uses a liquid transport module having a check valve as a relay. In order to achieve the above purpose, the present invention provides a liquid transport module which is connected by a liquid storage tank and a pumping unit, and includes: a first fluid guiding body, and a first water guiding channel group having a plurality of flow channel connections. An inlet and an outlet for a working fluid to flow in and out, wherein a part of the flow path of the first diversion channel group is respectively provided with a check valve to limit the flow direction of the working fluid; and a second guiding fluid to abut the first fluid guiding body And a second diversion channel group having a plurality of flow channels communicating with the first diversion channel group, and the second flow guiding body is provided with a plurality of ports respectively connecting the first diversion channel group and the second diversion channel a group; wherein the ports are respectively connected to the liquid tank and the pump unit. The present invention further provides a liquid cooling system, comprising: a first fluid guiding body, a first water guiding channel group having a plurality of flow channels connected to an inlet and an outlet, and the inlet is connected to a liquid cold row, the outlet connection a water-cooling head, wherein a part of the flow passages of the first diversion channel group is respectively provided with a check valve; a second fluid guide is connected to the first fluid guide, and a second diversion channel group is provided with a plurality of flow passages The first guiding water channel group, wherein the second guiding fluid is provided with a plurality of ports respectively communicating with the first guiding water channel group and the second guiding water channel group; a liquid storage tank connecting the second guiding fluid, And having a reservoir inlet and a reservoir outlet respectively communicating the first and second conduits through the two ports of the second fluid; a pumping unit having at least one first pump Having a first pump inlet and a first pump outlet through the other two ports of the second fluid to communicate with the flow path of the second fluid. The first guiding fluid comprises a first portion and a second portion, the first guiding channel group comprising a first flow channel, a second flow channel and a third flow channel disposed in the first portion and disposed in the second portion a fourth flow path, a fifth flow path and a sixth flow path, the first flow path being connected to the fourth flow path via a first check valve, the second flow path being connected via a second check valve a fifth flow passage, the third flow passage is connected to the fifth flow passage via a third check valve, the sixth flow passage is connected to the third flow passage via a connecting pipe, wherein the inlet communicates with the first flow passage, The outlet communicates with the third flow path. The second guiding fluid abuts the first guiding fluid, and comprises a third portion corresponding to a fourth portion, the second guiding channel group comprising a seventh portion disposed between the third portion and the fourth portion a flow channel and an eighth port; the plurality of ports include a first port, a second port, a third port, a fourth port, and a fifth port disposed in the third portion And a sixth port, a seventh port, an eighth port, a ninth port, a tenth port and an eleventh port disposed in the fourth part. The first port and the second port are located in a region other than the seventh channel and the eighth channel, and the first port corresponds to a first channel that communicates with the first fluid, the second channel The port corresponds to a sixth flow channel that communicates with the first fluid guide, and the third port and the fourth port communicate with the seventh flow channel of the second fluid guide and are respectively located at two ends of the seventh flow channel, and the The third port corresponds to a second flow channel that communicates with the first fluid guide, the fourth port corresponds to a fourth flow channel that communicates with the first fluid guide, and the fifth port communicates with the eighth flow of the second fluid guide And corresponding to the fifth flow path connecting the first fluid guide. The sixth port corresponds to the first port that communicates with the third portion, the seventh port and the eighth port communicate with the seventh channel of the third portion, and the seventh port corresponds to the third portion a second port, the ninth port and the tenth port are connected to the eighth channel and are respectively located at two ends of the eighth channel, and the ninth port corresponds to the fifth port of the third portion The eleventh port corresponds to the second port that communicates with the third portion. The liquid storage tank has a storage tank inlet and a storage tank outlet, and a sixth port and a seventh port connected to the second fluid guide, which are removable via the two joints; the pump unit includes a first pump Having a first pump inlet and a first pump outlet, the eighth port and the tenth port of the second fluid guide are removably connected via the two joints. The pump unit includes a second pump having a second pump inlet and a second pump outlet. The ninth port and the eleventh port are connected to the second fluid through the two joints. The foregoing further includes a detecting unit detecting a liquid storage amount in the liquid storage tank and a rotation speed of the pumping unit. The foregoing ports are connected to the liquid storage tank and the ports and the pump unit through a joint. The aforementioned joint is a quick release joint.

The above object of the present invention, as well as its structural and functional features, will be described in accordance with the preferred embodiments of the drawings. Referring to FIG. 1 , a liquid cooling system 10 includes a liquid cold discharge 11 (or a cooling water drain), a water cooling head 12 , a liquid storage tank 51 , a pump unit 52 , and a liquid transfer module 20 . The liquid cold discharge 11 is connected to the liquid transport module 20 through a first conduit 111 and to the water-cooling head 12 via a second conduit 112. The water-cooling head 12 is connected to the liquid transport module 20 through a third conduit 121. The liquid cold discharge 11 and the water cooling head 12 communicate with the liquid storage tank 51 and the pump unit 52 through the liquid transport module 20. The pump unit 52 includes at least one pump. In the present drawing, the two pumps are the first pump 521 and the second pump 522, respectively, but it is not limited thereto, and only one pump may be used, which will be detailed later. Describe the implementation of using a pump. The water-cooling head 12 is configured to contact a heat source, and the tropical heat of the heat source is moved by a working liquid, and the working liquid flows into the liquid cold discharge 11 through the second conduit 112 to dissipate heat, and the heat-dissipated working liquid passes through the first The conduit 111 flows into the liquid transport module 20 and flows through the reservoir 51 and the pump unit 52 via the liquid transport module 20. The liquid storage tank 51 is pre-filled with liquid for replenishing the amount of liquid in the liquid cooling system 10, and the pumping unit 52 is used to drive or pressurize the working liquid flow and flow rate in the liquid cooling system 10. The liquid transfer module 20 includes a first fluid guide 21 and a second fluid guide 22. The first fluid guide 21 is provided with a first flow channel group having a plurality of flow channels connected to an inlet 213 and an outlet 214 for the liquid. The working fluid of the cooling system 10 flows into and out of the water, wherein the inlet 213 is connected to the liquid cold discharge 11 through the first conduit 111, and the outlet 214 is connected to the water-cooling head 12 through the third conduit 121. The second guiding fluid 22 is provided with a second guiding water channel group having a plurality of flow channels communicating with the first guiding water channel group, and the second guiding fluid 22 is provided with a plurality of ports respectively communicating with the first guiding channel group and the a second diversion channel group; wherein the ports are connected to the reservoir 51 and the pump unit 52, respectively. The liquid transfer module 20 serves as a relay transfer between the liquid storage tank 51 and the pump unit 52 and the water-cooling head 12 and the liquid cold discharge 11 , and the liquid storage tank 51 or the pump unit 52 is replaced. At least one of the pumps assists the liquid cooling system 10 to continue to operate without stopping operation due to replacement. The internal structure of the liquid transport module 20 will be described in detail below. As shown in FIG. 2A and FIG. 2B, referring to FIG. 1 together, the first conductive fluid 21 of the liquid transport module 20 includes a first portion 211 and a second portion 212 which are arranged up and down, the inlet 213 and the An outlet 214 is disposed in the first portion 211, and the first diversion channel component is disposed in the first portion 211 and the second portion 212. The second fluid guide 22 includes a third portion 221 corresponding to a fourth portion 222, wherein the third portion 221 is butted against the first portion 211 and the second portion 212 of the first channel fluid 21, and the second water guiding group is disposed. Between the third portion 221 and the fourth portion 222, the plurality of ports are disposed in the third portion 221 and the fourth portion 222, wherein the port at the fourth portion 222 is used to connect the liquid tank 51 and the pump unit 52. Continuing to refer to FIGS. 3A and 3B, together with reference to FIGS. 2A and 2B, the first diversion channel group of the first fluid guide 21 includes a side disposed on the side of the first portion 211 facing the second fluid guide 22 a first flow path p1, a second flow path p2 and a third flow path p3, and a fourth flow path p4 and a fifth flow disposed on a side of the second portion 212 facing the second fluid guide 22 Road p5 and a sixth flow path p6. A first check valve 241 is connected to the first flow path p1 and the fourth flow path p4; a second check valve 242 is connected to the second flow path p2 and the fifth flow path p5; a third check valve 243 The third flow path p3 and the fifth flow path p5 are connected; a communication pipe 25 is connected to the third flow path p3 and the sixth flow path p6. Furthermore, the first side of the first portion 211 and the second portion 212 facing each other, that is, the lower side of the first portion 211 and the upper side of the second portion 212 are respectively provided with a first valve body upper hole 241a and a first The valve body lower hole 241b communicates with the first flow path p1 and the third flow path p3, respectively; and a second valve body upper hole 242a and a second valve body lower hole 242b respectively communicate with the second flow path p2 and a fifth flow path p5; and a third valve body upper hole 243a and a third valve body lower hole 243b respectively communicate with the third flow path p3 and the fifth flow path p5; and a communication pipe upper connection hole 251a and a connection The pipe lower connecting holes 251b communicate with the third flow path p3 and the sixth flow path p6, respectively. The first check valve 241 is connected to the first valve body upper hole 241a and the first valve body lower hole 241b; the two ends of the second check valve 242 are connected to the second valve body upper hole 242a. And a second valve body lower connecting hole 242b; and a third valve body upper connecting hole 243a and a third valve body lower connecting hole 243b are connected to both ends of the third check valve 243; and two ends of the connecting pipe 25 are connected The communication tube upper connection hole 251a and the communication tube lower connection hole 251b. The first check valve 241, the second check valve 242, and the third check valve 243 have directionality for restricting the flow direction of the liquid, wherein the directivity of the first check valve 241 and the second check valve 242 Downward, the third check valve 243 is oriented upward. Further, the first to third check valves 241 to 243 may use a generally known check valve structure, for example, as shown in FIG. 3B, with the first check valve 241 as an explanation for the other second and third inverses. The valve bodies 242 and 243 have the same structure. The first check valve 241 is provided with a valve body passage 2411 extending through the first check valve 241. The valve body passage 2411 is provided with an elastic member 2412 and a plug body 2413. The valve body passage 2411 has a passage opening 2414 slightly smaller than the plug body 2413. In the normal state, the plug body 2413 is pressed against the elastic member 2412 to close the passage opening 2414, but when the plug body 2413 is properly applied by the working fluid pressure The pressure shifts and forces the resilient member 2412 to compress to open the passage opening 2414 to pass the working fluid through the check valve 241. Please refer to FIGS. 4A, 4B, 4C and 4D for reference. Referring to FIGS. 2A and 2B together, the second drainage group of the second fluid guide 22 includes the third portion 221 and the fourth portion. a seventh flow path p7 and an eighth flow path p8 between the portions 222; the plurality of port openings include a first port a1, a second port a2, and a third port disposed in the third portion 221 a port a3, a fourth port a4 and a fifth port a5; and a sixth port a6, a seventh port a7, an eighth port a8, and a ninth port disposed in the fourth portion 222 The port a9, the tenth port a10 and the eleventh port a11. The first port a1 and the second port a2 of the third portion 221 are located in a region other than the seventh channel p7 and the eighth channel p8, and the first port a1 is connected to the first port. a first flow path p1 of the fluid 21 corresponding to the sixth flow path p6 of the first conductive fluid 21, the third opening a3 and the fourth opening a4 communicating with the second conductive fluid 22 The seventh port p7 is located at both ends of the seventh channel p7, and the third port a3 corresponds to the second channel p2 that communicates with the first fluid guide 21, and the fourth port a4 corresponds to the first channel A fourth flow path p4 of the fluid guide 21 communicates with the eighth flow path p8 of the second conductive fluid 22 and correspondingly to the fifth flow path p5 of the first conductive fluid 21. Furthermore, the sixth port a6 of the fourth portion 222 corresponds to the first port a1 that communicates with the third portion 221, and the seventh port a7 and the eighth port a8 communicate with the third portion 221. a seventh flow path p7, and the seventh port a7 corresponds to the second port a2 of the third portion 221, the ninth port a9 and the tenth port a10 are connected to the eighth channel p8 and are respectively located at the eighth port Both ends of the flow path p8, and the ninth port a9 corresponds to the fifth port a5 of the third portion 221, and the eleventh port a11 corresponds to the second port a2 of the third portion 221. Please refer to FIG. 2C. Referring to FIGS. 2A and 2B together, the aforementioned plurality of joints c1 to c6 include a male connector and a female connector, and the male or female connectors of the connectors c1 to c6 are either The sixth to eleventh ports a6 to a11 of the fourth portion 222 of the second fluid guide 22 are respectively connected, and the male or female connectors of the connectors c1 to c6 are respectively connected to the reservoir 51. And at least one pump of the pump unit 52. The liquid storage tank 51 has a liquid tank inlet 511 and a liquid tank outlet 512. The sixth opening a6 and the seventh opening a7 connecting the second fluid guiding body 22 are removable via the two joints c1 and c2. The first pump 521 of the pump unit 52 has a first pump inlet 5211 and a first pump outlet 5212. The eighth port of the second fluid guide 22 is removably connected via the two joints c3 and c4. A8 and the tenth port a10. The second pump 522 has a second pump inlet 5221 and a second pump outlet 5222. The ninth port a9 and the eleventh port of the second fluid guide 22 are removably connected via the two connectors c5 and c6. Mouth a11. Furthermore, the first pump 521 and the second pump 522 are arranged in series by the ninth port a9, the tenth port a10, and the eighth channel p8. Therefore, when the working fluid successively passes through the first pump 521 and the second pump 522, the effect of being pressurized is increased, and the liquid pressure and the flow speed are increased. Furthermore, before the male and female connectors of the two connectors c1 and c2 between the liquid storage tank 51 and the liquid transport module 20 are not turned on, the working liquid in the liquid transport module 20 does not flow to the liquid storage. Box 51. Similarly, before the male and female connectors of the connectors c3 to c6 between the at least one pump and the liquid transport module 20 of the pump unit 52 are not connected, the working fluid in the liquid transport module 20 does not circulate. The detailed structure and operation of the joints c1 to c6 to the pump unit 52 will be described later in detail. The following shows the flow of the working fluid through the liquid transport module 20. For the sake of clarity, the parts in the figure will be decomposed and the flow paths of the liquids will be indicated by different arrows and lines, but the parts are actually used in the present invention. Connected together as shown in Figure 1 above. Please refer to the fifth pumping block 20 and the first pump 521 and the second pump 522 of the pump unit 52, which are connected to the inlet and the second pump 522. 213 entering the liquid transport module 20 first flows along the first flow path F1 through the water tank 51 (as shown in FIG. 5A) into the seventh flow path p7, and then along the seventh flow path p7 and then along the second flow path F2 After flowing through the first pump 521, it enters the eighth flow path p8 (as shown in FIG. 5B), then flows along the eighth flow path p8 and then along the third flow path F3 through the second pump 522 to enter the sixth flow. The track p6 then flows out of the outlet 241 through the third flow path p3 (as shown in Fig. 5C). Furthermore, as shown in the sixth figure, in an implementation, when the liquid storage tank 51 is not connected to the liquid transport module 20, the working liquid enters the inlet 213 and passes through the first reverse flow along the first flow passage 231. Stopping valve 241, then entering the seventh flow path p7 from the fourth port a4, and then flowing from the seventh flow path p7 through the eighth port a8 into the first pump 521 through the joint c3, and then from the first A pump 521 flows out through the joint c4 and the tenth port a10 into the eighth flow path p8, and then flows from the ninth port a9 into the second pump 522 via the joint c5, and flows out from the second pump 522. The working liquid passes through the joint c6 and the eleventh port a111 and the second port a2, and then passes through the switch tube 25 and the third flow path p3 along the sixth flow path p6, and then flows out from the outlet 214. Furthermore, as shown in the seventh and eighth diagrams, the pump unit has only one pump connected to the liquid transport module 20, and one embodiment is as shown in the seventh figure, and the pump unit is only connected by the first pump 521. The liquid transfer module 20, after the working liquid enters from the inlet 213, enters the liquid storage tank 51 through the first flow path p1 and the first port a1 and the sixth port a6 and the joint c1, and then is stored The liquid tank 51 flows out through the joint c2 and the seventh port a7, and then enters the first pump 521 through the eighth port a8 and the joint c3 along the seventh channel p7, and then from the first pump 521 After flowing out, the tenth port a10 is passed, then the fifth port a5 is passed along the eighth channel p8, and then the third channel is passed along the fifth channel p5 and the third check valve 243. After p3, it flows out from the outlet 214. In another embodiment, as shown in the eighth embodiment, the pump unit 52 only connects the second pump 522 to the liquid transfer module 20, and after the working liquid enters from the inlet 213, passes through the first flow path p1 and the first A port a1 and the sixth port a6 and the joint c1 enter the liquid storage tank 51, and then flow out from the liquid storage tank 51 through the joint c2 and the seventh port a7, and then pass along the seventh flow path p7. The third port a3 flows into the fifth flow path p5 along the second flow path p2 and the second check valve 242, and flows through the fifth through port a5 and the ninth port from the fifth flow path p5. A9 and the joint c5 enter the second pump 522, and then flow out from the second pump 522 along the joint c6 and the eleventh port a11 and the second port a2 into the sixth channel p6, and then along the communication The tube 25 and the third flow path p3 flow out from the outlet 214. Continuing to refer to Figures 9A and 9B, each of the aforementioned joints c1 to c6 uses, for example, a generally known quick release joint. The present description takes the joint c1 as an example, and the other joints c2 to c6 have the same structure as the joint c1. The c1 system includes a female connector c1f and a male connector c1m. The female connector c1f is provided with a female connector channel c11f extending through the female connector c1f. The female connector channel c11f is provided with a female connector elastic member c12f and a female connector plug body c13f. The female connector channel c11f has a female connector passage port c14f. The hole diameter is slightly smaller than the diameter of the female plug body c13f. When the female connector plug c13f is not in contact with the male connector c1m, the female connector plug member c13f is closed by the female connector elastic member c12f to close the female connector passage port c14f. The male connector c1m is provided with a male connector channel c11m extending through the male connector c1m and coaxial with the female connector channel c11f. The male connector channel c11m is provided with a male connector elastic member c12m and a male connector plug body c13m. The male connector plug The body c13m is coaxial with the female connector plug body c13f, and the diameter of the male connector passage port c14m in the male connector passage c11m is slightly smaller than the diameter of the male connector plug body c13m, and the male connector plug is not in the state of being mated with the female connector c1f. The body c13m is closed by the male joint elastic member c12m to close the male joint passage port c14m. Therefore, the working fluid does not conduct until the female connector c1f has not been sleeved with the male connector c1m. However, when the female connector c1f is sleeved with the male connector c1m, the female connector body c13f and the male connector body c13m interact to be displaced, forcing the female connector elastic member c12f and the male connector elastic member c12m to retract and open the same. The female joint passage port c14f and the male joint passage c14m are such that the working fluid passes through the female joint passage c11f and the male joint passage port c11m. In the present embodiment, the male connector c1m of the connector c1 is connected to the reservoir 51, and the female connector c1f is connected to the sixth port a6 of the liquid transport module 20 (as shown in FIGS. 2A to 2C). Referring to FIG. 10, a detecting unit 40 detects a liquid storage amount in the liquid storage tank 51 to monitor whether the liquid storage amount is reduced to a preset low value, if the liquid storage tank 51 is used. The liquid storage amount within the preset low value can be removed and replaced with a new liquid storage tank 51. The detection unit 40 is also used to detect the rotation speed of the pump unit 52, for example, detecting the rotation speed of the first pump 521 and/or the second pump 522 to monitor the first pump 521. And/or whether the second pump 522 is functioning properly. If the first pump 521 or the second pump 522 does not operate normally, for example, below normal speed or no speed, the abnormally operating pump can be removed and replaced. Through the above implementation, the liquid transport module 20 of the present invention is applied to the liquid cooling system 10 as a relay for transferring a working liquid between the liquid storage tank 51 and the pump unit 52 and the water cooling head 12 and the liquid cold discharge 11 . Transmission, the water tank 51 can still maintain the uninterrupted operation of the liquid cooling system. Furthermore, the liquid transport module 20 of the present invention can selectively connect two or more pumps or only one pump, that is, the liquid transport module 20 can connect the first pump 521 and the second pump. The pump 522 or only the first pump 521 or the second pump 522 is connected. Therefore, when either of the first pump 521 and the second pump 522 is inoperable, the liquid cooling system can still be maintained uninterrupted. Moreover, the uninterrupted operation of the liquid cooling system 10 can still be maintained when the first pump 521 or the second pump 522 is removed and replaced. Furthermore, at least the first pump 521 and the second pump 522 are connected in series by the flow path to pressurize the working fluid to increase the fluid pressure and the flow speed. The present invention has been described in detail above, but the above description is only a preferred embodiment of the present invention, and the scope of the present invention cannot be limited. That is, all changes and modifications made in accordance with the scope of this creation application shall remain covered by the patents of this creation.

10‧‧‧Liquid cooling system

11‧‧‧Liquid cold discharge

111‧‧‧First catheter

112‧‧‧Second catheter

12‧‧‧Water cooled head

121‧‧‧ Third catheter

20‧‧‧Liquid transfer module

21‧‧‧First Conductor

211‧‧‧The first part

212‧‧‧Part II

213‧‧‧ Import

214‧‧‧Export

22‧‧‧Second fluid

221‧‧‧Part III

222‧‧‧Part IV

P1～p8‧‧‧first to eight flow paths

241‧‧‧First check valve

241a‧‧‧The first valve body is connected to the hole

241b‧‧‧first valve body lower hole

2411‧‧‧ valve body passage

2412‧‧‧Flexible components

2413‧‧‧ body

2414‧‧‧ passage

242‧‧‧Second check valve

242a‧‧‧Second body body upper hole

242b‧‧‧Second body body lower hole

243‧‧‧3rd check valve

243a‧‧‧The third valve body is connected to the hole

243b‧‧‧3rd body body lower hole

25‧‧‧Connected pipe

251a‧‧‧Connecting holes in the connecting pipe

251b‧‧‧Connected holes under the connecting pipe

A1~a11‧‧‧first to eleven ports

C1 to c6‧‧‧ joint

C1f‧‧‧ female connector

C11f‧‧‧ female joint channel

C12f‧‧‧ female joint elastic element

C13f‧‧‧ female connector body

C14f‧‧‧ female connector channel

C1m‧‧‧ male connector

C11m‧‧‧ male connector channel

C12m‧‧‧ male connector elastic element

C13m‧‧‧ male connector body

C14m‧‧‧ male connector passage

40‧‧‧Detection unit

51‧‧‧Liquid tank

511‧‧‧tank inlet

512‧‧‧reservoir outlet

52‧‧‧ pump unit

521‧‧‧First pump

5211‧‧‧First pump inlet

5212‧‧‧First pump outlet

522‧‧‧Second pump

5221‧‧‧Second pump inlet

5222‧‧‧Second pump outlet

Figure 1 is a schematic diagram of the liquid cooling system of the present invention; Figures 2A and 2B are exploded views of different perspectives of the liquid transport module of the present invention; Figure 2C shows the female connector and the male connector respectively connected to the liquid transfer mode Schematic diagram of the decomposition of the group and the water tank and the pump; Figure 3A is a schematic diagram of the decomposition of the first guiding fluid for the creation; Figure 3B is a schematic sectional view of the check valve of the creation example; Figures 4A to 4D are A schematic diagram of creating a second fluid guide; Figures 5A to 8 are schematic diagrams of liquid flow for various implementations of the present invention; Figures 9A and 9B are schematic cross-sectional views of the joint example of the creation; Figure 10 is a representation of the present invention including a Detective Schematic diagram of the measurement unit.

Claims (19)

A liquid transmission module is connected by a liquid storage tank and a pumping unit, comprising: a first guiding fluid, and a first guiding water channel group having a plurality of flow passages connected to an inlet and an outlet for a working liquid to flow in And flowing out, wherein a part of the flow passages of the first diversion channel group respectively are provided with a check valve to limit the flow direction of the working fluid; a second guiding fluid is connected to the first guiding fluid, and a second diversion channel group is provided The plurality of flow channels are connected to the first water guiding channel group, and the second gas guiding body is provided with a plurality of ports respectively connected to the first water guiding channel group and the second water guiding channel group; wherein the ports are respectively connected to the a reservoir and the pump unit. The liquid transport module of claim 1, wherein the first conductive fluid comprises a first portion and a second portion, the first water guiding group comprising a first flow path and a second portion disposed in the first portion a flow channel and a third flow channel and a fourth flow channel, a fifth flow channel and a sixth flow channel disposed in the second portion, the first flow channel connecting the fourth flow via a first check valve The second flow passage is connected to the fifth flow passage via a second check valve, and the third flow passage is connected to the fifth flow passage via a third check valve, and the sixth flow passage is connected via a connecting pipe. The third flow passage, wherein the inlet communicates with the first flow passage, and the outlet communicates with the third flow passage. The liquid transport module of claim 2, wherein the second fluid guide abuts the first fluid guide, and includes a third portion corresponding to a fourth portion, the second water guide group comprising the first a seventh flow channel and an eighth flow channel between the third portion and the fourth portion; the plurality of port openings include a first port, a second port, and a third port disposed in the third portion a port, a fourth port and a fifth port, and a sixth port, a seventh port, an eighth port, a ninth port, and a tenth port disposed in the fourth portion Mouth and an eleventh port. The liquid transfer module of claim 3, wherein the first port and the second port are located in an area other than the seventh channel and the eighth channel, and the first port corresponds to the first port a first flow channel of the fluid guide, the second port corresponding to the sixth flow channel connecting the first fluid guide, the third port and the fourth port communicate with the seventh flow channel of the second fluid guide and respectively Located at two ends of the seventh flow channel, and the third port corresponds to a second flow channel that communicates with the first fluid guide, and the fourth port corresponds to a fourth flow channel that communicates with the first fluid guide, the fifth port The port communicates with the eighth flow path of the second fluid guide and corresponds to the fifth flow path that communicates with the first fluid guide. The liquid transfer module of claim 4, wherein the sixth port corresponds to the first port that communicates with the third portion, and the seventh port and the eighth port communicate with the third stream of the third portion And the seventh port corresponds to the second port of the third portion, the ninth port and the tenth port are connected to the eighth channel and are respectively located at two ends of the eighth channel, and the first port The nine-port corresponds to the fifth port of the third portion, and the eleventh port corresponds to the second port that communicates with the third portion. The liquid transfer module of claim 5, wherein the liquid storage tank has a liquid tank inlet and a liquid tank outlet, and the sixth and seventh passages of the second fluid guide are removably connected via the two joints. The pump unit includes a first pump having a first pump inlet and a first pump outlet via the two joints for removing the eighth and third ports of the second fluid guide . The liquid transport module of claim 6, wherein the pump unit comprises a second pump having a second pump inlet and a second pump outlet for removably connecting the second fluid guide via two joints The ninth port and the eleventh port. The liquid transfer module of claim 1, further comprising a detecting unit for detecting a liquid storage amount in the liquid storage tank and a rotational speed of the pumping unit. The liquid transfer module of claim 1, wherein the ports are connected to the reservoir and the ports are connected to the pump unit by a joint. A liquid cooling system comprising: a liquid transfer module comprising: a first fluid guide, a first water guide group having a plurality of flow channels connected to an inlet and an outlet, wherein the inlet is connected to a liquid cold row The outlet is connected to a water-cooling head, and a part of the flow path of the first diversion channel group is respectively provided with a check valve; a second guiding fluid is connected to the first guiding fluid, and a second guiding channel group is provided a plurality of flow channels are connected to the first water guiding channel group, and the second gas guiding body is provided with a plurality of ports respectively connected to the first water guiding channel group and the second guiding water channel group; a liquid storage tank is connected to the first a second fluid guiding body, and having a reservoir inlet and a reservoir outlet respectively communicating the first fluid guiding body and the second fluid guiding body through two of the second fluid guiding ports; and a pumping unit having at least one The first pump has a first pump inlet and a first pump outlet communicates with the flow path of the second fluid guide through the other two of the second fluid guides. The liquid cooling system of claim 10, wherein the first fluid guide comprises a first portion and a second portion, the first water guiding group comprising a first flow path and a second flow disposed in the first portion a third flow passage and a fourth flow passage, a fifth flow passage and a sixth flow passage disposed in the second portion, the first flow passage connecting the fourth flow passage via a first check valve The second flow path is connected to the fifth flow path via a second check valve. The third flow path is connected to the fifth flow path via a third check valve. The sixth flow path is connected via a connecting pipe. a third flow passage, wherein the inlet communicates with the first flow passage, and the outlet communicates with the third flow passage. The liquid cooling system of claim 11, wherein the second fluid guide abuts the first fluid guide and includes a third portion corresponding to a fourth portion, the second water guide group including the third portion a seventh flow path and an eighth flow path between the portion and the fourth portion; the plurality of ports including a first port, a second port, and a third port disposed in the third portion a fourth port and a fifth port, and a sixth port, a seventh port, an eighth port, a ninth port, and a tenth port disposed in the fourth portion And an eleventh port. The liquid cooling system of claim 12, wherein the first port and the second port are located in an area other than the seventh channel and the eighth channel, and the first port corresponds to the first port a first flow path of the fluid guide, the second port corresponding to the sixth flow path connecting the first fluid guide, the third port and the fourth port communicating with the seventh flow channel of the second fluid guide and respectively located The second port corresponds to a second channel that communicates with the first fluid, and the fourth port corresponds to a fourth channel that communicates with the first fluid. The port communicates with the eighth flow channel of the second fluid guide and corresponds to the fifth flow channel that communicates with the first fluid guide. The liquid cooling system of claim 13, wherein the sixth port corresponds to the first port that communicates with the third portion, and the seventh port and the eighth port communicate with the seventh channel of the third portion And the seventh port corresponds to the second port of the third portion, the ninth port and the tenth port are connected to the eighth channel and are respectively located at two ends of the eighth channel, and the ninth port The port corresponds to the fifth port of the third portion, and the eleventh port corresponds to the second port that communicates with the third portion. The liquid cooling system of claim 14, wherein the liquid storage tank is removably connected to the sixth port and the seventh port of the fourth portion of the second fluid guide via two joints; A pump removably connects the eighth port and the tenth port of the fourth portion of the second fluid guide via the two joints. The liquid cooling system of claim 15, wherein the pump unit has a second pump having a second pump inlet and a second pump outlet removably connected to the second fluid guide via the two joints. The ninth and eleventh ports of the fourth part. The liquid cooling system of claim 10, wherein the plurality of ports of the second fluid guide are connected to the reservoir and the pump unit via a joint. The liquid cooling system of claim 16 or 17, wherein each of the joints is a quick release joint. The liquid cooling system of claim 10, further comprising a detecting unit detecting a liquid storage amount in the liquid storage tank and a rotation speed of the pumping unit.