TWM586040U - Water-cooling pump structure with check valve and water cooling module thereof - Google Patents

Abstract

A water-cooled pump structure with a check valve and a water-cooled module thereof include a first pump unit, a first check valve, a second pump unit, a second check valve, and a first joint. Group, a second connector group, a tube body group and a heat dissipation unit, the first pump unit forms a first pump chamber and has a first water inlet and a first water outlet, the first backstop A valve is connected to the first water outlet. The second pump unit has a second pump chamber and has a second water inlet and a second water outlet. The second check valve is connected to the second water outlet. The water outlets are connected, and the first joint group has a first and second water inlets and a first water outlet, the first water inlet is correspondingly connected to the first check valve, and the second water inlet is connected to the first A second check valve, the second joint group has a third water inlet portion and a second and third water outlet portion, the second water outlet portion is correspondingly connected to the first water inlet, and the third water outlet portion is correspondingly connected to the second water inlet Water inlet, the pipe body has a first and second pipe body, the heat dissipation unit has an inlet and an outlet, and the two ends of the first pipe body are divided into Corresponding to the inlet and the first outlet communication portion, the second tube ends respectively and the third water communication with the outlet portion.

Description

Water-cooled pump structure with check valve and water-cooled module

This creation relates to a water-cooled pump structure with a check valve and a water-cooled module thereof, in particular to a water-cooled pump structure with a check valve and a water-cooled module thereof which can prevent the backflow of cooling liquid.

According to the current computer or electronics industry, a large number of processing chips are used, such as: central processing units and graphics chips, or other processing chips such as north and south bridges. Faster, the relative thermal energy generated during operation also increases, which is also called heating element. Because these heating elements can cause abnormal operation when the operating temperature is too high, and may even burn out, so in order to effectively reduce the heat, various heat sinks have also appeared on the market. It is closely attached to the overheating surface of these heating elements, so as to help them dissipate heat by conduction, convection or radiation, so as to keep these heating elements operating at normal working temperature.
Generally, the most common heat dissipation device is made by using a heat-conductive metal (such as aluminum or copper) through various processes. It is composed of a base, a plurality of cooling fins, and a cooling fan. The base is used to closely contact the heat sink. After the heating element, the heat energy is directly transmitted to the heat dissipation fins, and the surface is used to generate heat convection with the outside air, and then the heat energy is dissipated to the outside, or a heat pipe is used to enhance the heat dissipation effect. The heat pipe is A closed tube body is filled with a heat-dissipating medium in a liquid state. The main component of the heat-dissipating medium is water, and the rest is a special component that can increase the heat transfer capacity of the liquid. One end of the heat pipe is an evaporation end and is in contact with the heating element, so as to absorb the heat and cause the heat sink to absorb heat and evaporate to a gaseous state, and then move to the condensing end of the other end of the heat pipe to dissipate heat to form A closed heat dissipation cycle stroke, and the heat dissipation medium can be used to take away a large amount of heat at a time, thereby achieving the purpose of improving heat dissipation efficiency.
In addition, there is a water-cooled heat dissipation module that simply uses liquid circulation to dissipate heat. It uses a circulating pump to drive a cooling liquid (usually water) that has a large specific heat and can absorb heat. When it passes through the heating element, it can absorb heat at the same time, and Use the flow of the cooling liquid to take heat away from the heating element, and discharge heat in the passing pipeline or water storage tank to achieve the purpose of dissipating heat; however, in order to increase the heat dissipation efficiency, some industries will use water cooling to dissipate heat. The module uses upper and lower stacked pumps to dissipate heat. It collects the cooling liquid in each pump and then flows out through the pipe body. In this way, the cooling liquid is circulated and cooled continuously. However, if one of the installation methods is used, When the pump is damaged, the internal cooling liquid cannot be driven due to the damage of the pump. At this time, the internal cooling liquid will cause a backflow problem, and the liquid cannot be smoothly circulated to dissipate heat, resulting in worse heat dissipation efficiency.

Therefore, in order to effectively solve the above problems, the main purpose of this creation is to provide a water-cooled pump structure with a check valve that can prevent the cooling liquid from flowing back.
The secondary objective of this creation is to provide a water-cooled pump structure with a check valve that can greatly improve heat dissipation efficiency.
The secondary objective of this creation is to provide a water-cooled module that prevents the cooling liquid from flowing back.
The secondary purpose of this creation is to provide a water-cooled module that can greatly improve heat dissipation efficiency.
To achieve the above purpose, the present invention provides a water-cooled pump structure with a check valve, which includes a first pump unit, a first check valve, a second pump unit, a second check valve, A first connector group and a second connector group. The first pump unit has a first pump casing to form a first pump chamber. The first pump casing has a first water inlet and a first The first pumping chamber is connected to the first water inlet and the first water outlet. The first check valve is correspondingly connected to the first water outlet. The second pump unit has a The second pump casing forms a second pump chamber. The second pump casing has a second water inlet and a second water outlet. The second pump chamber is connected to the second water inlet and the first water outlet. Two water outlets, the second check valve is correspondingly connected with the second water outlet, the first joint group has a first water inlet part, a second water inlet part and a first water outlet part, the first A water inlet part is correspondingly connected to the first check valve, the second water inlet part is correspondingly connected to the second check valve, and the second joint group has a third A dewatering part and the second outlet portion and a third outlet portion, the portion corresponding to the second outlet connected to the first inlet, the portion corresponding to the third outlet connected to the second inlet.
In order to achieve the above purpose, the present invention provides a water cooling module, which includes a first pump unit, a first check valve, a second pump unit, a second check valve, a first connector group, A second connector group, a tube body group, and a heat dissipation unit. The first pump unit has a first pump housing to form a first pump chamber. The first pump housing has a first water inlet and A first water outlet, the first pump chamber is connected to the first water inlet and the first water outlet, the first check valve is correspondingly connected to the first water outlet, and the second pump The unit has a second pump casing forming a second pumping chamber. The second pump casing has a second water inlet and a second water outlet. The second pumping chamber is connected to the second inlet. Water outlet and second water outlet, the second check valve is correspondingly connected with the second water outlet, the first joint group has a first water inlet, a second water inlet, and a first water outlet The first water inlet part is correspondingly connected to the first check valve, the second water inlet part is correspondingly connected to the second check valve, and the second joint group has A third water inlet portion, a second water outlet portion, and a third water outlet portion, the second water outlet portion is correspondingly connected to the first water inlet, the third water outlet portion is correspondingly connected to the second water inlet, and the pipe body group has a A first pipe body and a second pipe body, one end of the first pipe body is correspondingly connected to the first water outlet portion, one end of the second pipe body is correspondingly connected to the third water inlet portion, and the heat dissipation unit has An inlet and an outlet, the inlet corresponding to the other end of the first pipe body, the outlet corresponding to the other end of the second pipe body, a circulation chamber is formed inside the heat dissipation unit A cooling liquid is circulated, and the circulation chamber is in communication with the inlet and the outlet.
Through the design of this structure, when the water cooling module starts to operate, the cooling liquid in the heat dissipation unit will first flow through the outlet to the second tube and then into the third water inlet, and then borrow After the cooling liquid is divided by the third water inlet of the second connector group, a part of the liquid will flow from the second water outlet to the second communication pipe, and then enter the first water inlet through the first water inlet. In the first pumping chamber of the pumping unit, the cooling liquid in the first pumping chamber passes through the first water outlet and flows into the first space of the first check valve, and the first space The provided first seal will push the first seal forward due to the pressure of the cooling liquid, so that the cooling liquid can smoothly flow into the second space, and then enter the first communication pipe and then flow into the The first water inlet of the first joint group;
The other part of the cooling liquid that is diverted will flow from the third water outlet to the fourth communication pipe, and then enter the second pump chamber of the second pump unit through the second water inlet. Then, the cooling liquid in the second pump chamber will flow through the second water outlet to the third space of the second check valve, and the second seal provided in the third space will be caused by the cooling liquid. The pressure pushes the second seal forward to open, so that the cooling liquid can smoothly flow into the fourth space, then enter the third communication pipe, and then flow into the second water inlet of the first joint group. After being collected with the cooling liquid flowing in from the first water inlet part, and then discharged to the first water outlet part, the cooling liquid flows back to the circulation cavity of the heat dissipation unit through the first pipe body. In the room, the circulation is repeated back and forth in this way to complete the liquid cooling cycle of the water cooling module.
Through the design that the first and second check valves are respectively installed at the first and second water outlets, when any one of the pump units is destroyed and cannot operate, and the cooling liquid cannot flow out, the first check valve is passed. The first seal (or the second seal) inside the (or the second check valve) prevents the cooling liquid from flowing back to the first pump chamber (or the second pump chamber) to prevent cooling. Liquid backflow, and can greatly improve the effect of heat dissipation.

The above-mentioned purpose of this creation and its structural and functional characteristics will be explained according to the preferred embodiments of the drawings.
Please refer to FIGS. 1A and 1B, which are an exploded view and a three-dimensional combined view of the first embodiment of the water-cooled pump structure with a check valve. As shown, a water-cooled pump structure with a check valve 2, which includes a first pump unit 20, a first check valve 21, a second pump unit 22, a second check valve 23, a first connector group 24 and a second connector group 25, The first pump unit 20 has a first pump housing 201 to form a first pump chamber 2011, and a first water inlet 202 and a first water outlet 203 are opened on the first pump housing 201. The first pump chamber 2011 is connected to the first water inlet 202 and the first water outlet 203, and the first water outlet 203 is correspondingly connected to the first check valve 21;
Continued to refer to Figures 2A, 2B, and 2C, which are the internal structure of the first check valve. The first check valve 21 further has a first valve body 211 and a first valve body 211. A first space 212 and a second space 213 are formed inside the first space. The first space 212 has a first seat portion 2121, the second space 213 has a second seat portion 2131, and a first rod body 214 has a first A base 2143 and a first seal 2144. The two ends of the first rod body 214 extend to form a first extension end 2141 and a second extension end 2142. The first and second extension ends 2141 and 2142 are axially rotatable. The first and second seat portions 2121 and 2131 are movably inserted respectively, and the first seal 2144 is disposed on one side of the first base portion 2143 opposite to the first space 212. A first elastic element 215 The two ends abut against the first base portion 2143 of the first rod body 214 and the inner wall surface of the first valve body 211 respectively. The first water outlet 203 of the first pump unit 20 corresponds to the first space 212. Connected
The aforementioned second pump unit 22 has a second pump casing 221 to form a second pump chamber 2211, and a second water inlet 222 and a second water outlet 223 are opened on the second pump casing 221. The second pump chamber 2211 is connected to the second water inlet 222 and the second water outlet 223, and the second water outlet 223 is correspondingly connected to the second check valve 23;
Continued to refer to FIG. 2D, the second check valve 23 is described in a sectional view directly, and its appearance is the same as that of the first check valve 21 (see FIGS. 2A and 2B), so it is not According to another diagram, the second check valve 23 further has a second valve body 231, and a third space 232 and a fourth space 233 are formed inside the second valve body 231. The third space 232 has a A third seat portion 2321, the fourth space 233 has a fourth seat portion 2331, a second rod body 234 has a second base portion 2343 and a second seal 2344, and the two ends of the second rod body 234 extend to form a A third extension end 2341 and a fourth extension end 2342, the third and fourth extension ends 2341, 2342 are respectively movably inserted in the third and fourth seat portions 2321, 2331, and the second A seal 2344 is disposed on one side of the second base portion 2343 opposite to the third space 232, and two ends of a second elastic member 235 abut against the second base portion 2343 of the second rod body 234 and the second valve body 231, respectively. An internal wall surface, the second water outlet 223 of the second pump unit 22 is in communication with the third space 232 correspondingly;
The first pump unit 20 has a first communication pipe 26 and a second communication pipe 27. One end of the first communication pipe 26 corresponds to the second space 213 of the first check valve 21. One end of the second communication pipe 27 is correspondingly connected to the first water inlet 202 of the first pump unit 20;
The second pump unit 22 has a third communication tube 28 and a fourth communication tube 29. One end of the third communication tube 28 corresponds to the fourth space 233 of the second check valve 23. One end of the fourth communication pipe 29 is correspondingly connected to the second water inlet 222 of the second pump unit 22;
The first joint group 24 has a first side 241 and a second side 242. A first water inlet portion 2411 and a second water inlet portion 2412 are formed on the first side 241, and are formed on the second side 242. A first water outlet 2421 is in communication with the first and second water inlets 2411 and 2412. The first water inlet 2411 is connected to the first communication pipe 26 and is connected to the first The other end of a check valve 21, the second water inlet portion 2412 is connected to the third communication pipe 28 and is oppositely connected to the other end of the second check valve 23;
The second joint group 25 has a third side 251 and a fourth side 252. A second water outlet portion 2511 and a third water outlet portion 2512 are formed on the third side 251, and a first water outlet portion 2511 is formed on the fourth side 252. Three water inlets 2521, and the third water inlet 2521 is in communication with the second and third water outlets 2511, 2512. The second water outlet 2511 is connected to the second communication pipe 27 and is connected to the first water inlet. At the other end of 202, the third water inlet 2521 is connected to the fourth communication pipe 29 and is oppositely connected to the other end of the second water inlet 222;
Wherein, the first and second joint groups 24 and 25 are described by using a three-way joint in this embodiment, but are not limited thereto, and may also be a four-way joint or a multi-way joint, which are used in accordance with The number of water-cooled pump structures depends on the number of pumps. In other words, the creation is described by using the first and second pump units 20 and 22 (ie, two pump units). The principle can make the internal cooling liquid 5 have the function of diverting or collecting the cooling liquid 5 when passing through the first and second joint groups 24 and 25.
Please also refer to the 3A, 3B, 3C, and 3D drawings, which are a three-dimensional exploded view of the first embodiment of the creative water-cooling module, a schematic diagram of the implementation and a sectional view, and some components and components of the water-cooling module of this embodiment. The corresponding relationship between them is the same as the aforementioned water-cooled pump structure 2 with a check valve, so it will not be repeated here, and the water-cooled module includes the aforementioned water-cooled pump structure 2 with a check valve. It further includes a tube group 3 and a heat dissipation unit 4. The tube group 3 has a first tube body 31 and a second tube body 32. One end of the first tube body 31 corresponds to the first joint. The first water outlet 2421 of the group 24, and one end of the second pipe body 32 corresponds to the third water inlet 2521 of the second joint group 25;
The heat dissipation unit 4 has an inlet 41 and an outlet 42. The inlet 41 is in communication with the other end of the first water outlet 2421 of the first joint group 24 opposite to the first pipe body 31. The outlet 42 is The other end of the third water inlet 2521 opposite to the second joint group 25 is connected to the second pipe body 32;
In addition, in this embodiment, the heat dissipation module further has a water storage tank 6, one side of which is connected to the pipe body group 3 and the other side is connected to the inlet of the heat dissipation unit 4. 41 and the outlet 42 are correspondingly connected, and the water storage tank 6 may not need to be provided in this creation (as shown in FIG. 4), and can also achieve the effect of this case, which will be described first.
In addition, this creation is based on the description of the water-cooled module with the first and second pump units 20 and 22 (that is, two pump units), but it is not limited to this. It can be configured according to the user's design. Three sets (or more than three sets) of pump units are stacked (as shown in Figure 5). Of course, to further understand, the three-way connector is correspondingly converted to a four-way according to the number of configured pump units. Joints (or multi-way joints), and the corresponding number of connecting pipes and check valves must also be installed to form a complete water cooling module.
Through the structural design of the water-cooling module, when one side of the heat-dissipating unit 4 of the water-cooling module is in contact with a heating element (not shown in the figure) and starts to operate, first the cooling liquid 5 in the heat-dissipating unit 4 will pass through the outlet 42 flows into the water storage tank 6, and then flows into the second pipe body 32, and then flows into the third water inlet 2521, and then is cooled by the third water inlet 2521 of the second joint group 25 The liquid 5 is divided, and a part of the liquid flows from the second water outlet 2511 to the second communication pipe 27, and then enters the first pumping chamber of the first pumping unit 20 through the first water inlet 202. In 2011, then, the cooling liquid 5 in the first pumping chamber 2011 will flow through the first water outlet 203 and flow into the first space 212 of the first check valve 21, and the first space 212 provided in the first space 212 The first seal 2144 pushes the first seal 2144 toward the second space 213 due to the pressure of the cooling liquid 5, so that the cooling liquid 5 can smoothly flow into the second space 213 and then enter the second space 213. The first communication pipe 26 flows into the first water inlet 2411 of the first joint group 24 again;
After the cooling liquid 5 is shunted, another part of the liquid flows from the third water outlet 2512 to the fourth communication pipe 29, and then enters the second pump unit 22 through the second water inlet 222. In the pumping chamber 2211, the cooling liquid 5 in the second pumping chamber 2211 passes through the second water outlet 223 and flows into the third space 232 of the second check valve 23, and the third space The second seal 2344 provided in 232 will push the second seal 2344 toward the fourth space 233 due to the pressure of the cooling liquid 5, so that the cooling liquid 5 can smoothly flow into the fourth space 233. Then it enters the third communication pipe 28 and flows into the second water inlet portion 2412 of the first joint group 24, and is collected with the cooling liquid 5 flowing in from the first water inlet portion 2411 at the first joint group 24. After that, it is discharged to the first water outlet 2421 together. Then, the cooling liquid 5 passes through the first pipe body 31 and the water storage tank 6 in sequence and flows back to a circulation chamber 43 of the heat dissipation unit 4. (The circulation chamber 43 may be composed of a plurality of flow channels). The liquid cooling cycle of the water cooling module is described.
Through the design of the first and second check valves 21 and 23 respectively installed at the first and second water outlets 203 and 223 of the first and second pump units 20 and 22, when any of the pump units (That is, any one of the first pump unit 20 or the second pump unit 22 mentioned above, the component symbol descriptions of the 3C and 3D drawings contrasted in this embodiment are described using the first pump unit 20 as a representative) When the cooling liquid 5 cannot be driven due to inoperability, the cooling liquid 5 will cause a backflow problem, and when the cooling liquid 5 flows back, the circulation flow inside the water-cooled module will become unsmooth. The structure of the first seal 2144 (or the second seal 2344) inside the first check valve 21 (or the second check valve 23) created can prevent the cooling liquid 5 from flowing back to the first pump The chamber 2011 (or the second pumping chamber 2211) can be used to completely prevent the backflow of the cooling liquid 5 (obviously seen from the 3D diagram), and can also greatly improve the effect of heat dissipation.
In addition, in order to achieve better heat dissipation effect, at least one heat dissipation element (such as a heat dissipation fin, a water drain, etc.) may be added to the heat dissipation module, so as to perform heat exchange and heat dissipation for the cooling liquid 5.
As mentioned above, this creation has the following advantages compared to conventional knowledge:
1. Prevent cooling liquid from flowing back;
2. Greatly improve heat dissipation efficiency.
The creation has been described in detail above, but the above is only a preferred embodiment of the creation, and the scope of implementation of the creation cannot be limited. That is to say, all equal changes and modifications made in accordance with the scope of this creative application shall still be covered by the patent of this creative.

2‧‧‧ Water-cooled pump structure with check valve
20‧‧‧The first pump unit
201‧‧‧The first pump casing
2011‧‧‧The first pump chamber
202‧‧‧First water inlet
203‧‧‧First Outlet
21‧‧‧The first check valve
211‧‧‧The first valve body
212‧‧‧First Space
2121‧‧‧First Block
213‧‧‧Second Space
2131‧‧‧Second Block
214‧‧‧The first shaft
2141‧‧‧first extension
2142‧‧‧Second extension
2143‧‧‧First base
2144‧‧‧First Seal
215‧‧‧first elastic element
22‧‧‧Second Pump Unit
221‧‧‧Second pump casing
2211‧‧‧Second Pump Chamber
222‧‧‧Second water inlet
223‧‧‧Second Outlet
23‧‧‧Second check valve
231‧‧‧Second valve body
232‧‧‧Third Space
2321‧‧‧Third Block
233‧‧‧ Fourth Space
2331‧‧‧Fourth Block
234‧‧‧Second shaft
2341‧‧‧ Third extension
2342‧‧‧Fourth extension
2343‧‧‧Second Base
2344‧‧‧Second Seal
235‧‧‧Second elastic element
24‧‧‧The first connector group
241‧‧‧first side
2411‧‧‧First water intake department
2412‧‧‧Second water inlet
242‧‧‧second side
2421‧‧‧First Outlet
25‧‧‧Second connector set
251‧‧‧third side
2511‧‧‧Second Outlet
2512‧‧‧Third Outlet
252‧‧‧Fourth side
2521‧‧‧Third water intake
26‧‧‧First connecting pipe
27‧‧‧Second connecting pipe
28‧‧‧ third connecting pipe
29‧‧‧ Fourth connecting pipe
3‧‧‧Tube body group
31‧‧‧First tube
32‧‧‧Second tube body
4‧‧‧Cooling unit
41‧‧‧Entrance
42‧‧‧Export
43‧‧‧Circulation chamber
5‧‧‧ cooling liquid
6‧‧‧ water tank

FIG. 1A is an exploded perspective view of a first embodiment of a water-cooled pump structure with a check valve;
Figure 1B is a three-dimensional assembled view of the first embodiment of the water-cooled pump structure with a check valve;
Figure 2A is a three-dimensional exploded view of the first check valve of this creation;
Figure 2B is a three-dimensional combination diagram of the first check valve of this creation;
Figure 2C is a sectional view of the first check valve of this creation;
Figure 2D is a sectional view of the second check valve of this creation;
Figure 3A is an exploded perspective view of the first embodiment of the creative water cooling module;
Figure 3B is a schematic diagram of the implementation of the first embodiment of the creative water cooling module;
Figure 3C is a schematic cross-sectional view of the first embodiment of the creative water cooling module;
FIG. 3D is another schematic sectional view of the first embodiment of the creative water cooling module;
FIG. 4 is a three-dimensional combined view of the second embodiment of the creative water cooling module;
FIG. 5 is a three-dimensional combined view of the third embodiment of the creative water cooling module.

Claims (17)

A water-cooled pump structure with a check valve includes:
A first pump unit has a first pump casing forming a first pump chamber, the first pump casing has a first water inlet and a first water outlet, and the first pump chamber is Communicating with the first water inlet and the first water outlet;
A first check valve corresponding to the first water outlet;
A second pump unit has a second pump casing forming a second pump chamber. The second pump casing has a second water inlet and a second water outlet. The second pump chamber is Communicating with the second water inlet and the second water outlet;
A second check valve, which is correspondingly connected to the second water outlet;
A first connector group has a first water inlet portion, a second water inlet portion, and a first water outlet portion. The first water inlet portion is correspondingly connected to the first check valve, and the second water inlet portion is correspondingly connected. The second check valve; and a second joint group having a third water inlet portion, a second water outlet portion, and a third water outlet portion, the second water outlet portion is correspondingly connected to the first water inlet, and the third The water outlet is correspondingly connected to the second water inlet. The water-cooled pump structure with a check valve according to claim 1, wherein the first pump unit has a first communication pipe and a second communication pipe, and two ends of the first communication pipe are respectively connected The two ends of the first check valve and the first water inlet are connected to the first water inlet and the second water outlet respectively. The water-cooled pump structure with a check valve according to claim 1, wherein the second pump unit has a third communication pipe and a fourth communication pipe, and two ends of the third communication pipe are respectively connected to the A second check valve and a second water inlet, and two ends of the fourth communication pipe are respectively connected to the second water inlet and the third water outlet. The water-cooled pump structure with a check valve according to claim 1, wherein the first joint group further has a first side and a second side, and the first side has the first water inlet and the The second water inlet portion has the first water outlet portion on the second side, and the first and second water inlet portions communicate with the first water outlet portion. The water-cooled pump structure with a check valve according to claim 1, wherein the second joint group further has a third side and a fourth side, and the third side has the second water outlet portion and the A third water outlet, the fourth side has the third water inlet, and the second and third water outlets are in communication with the third water inlet. The water-cooled pump structure with a check valve according to claim 1, wherein the first check valve further has a first valve body, and the first valve body has a first space and a second space inside, The first space has a first seat portion, the second space has a second seat portion, a first rod body has a first base portion and a first sealing member, and two ends of the first rod body extend a first An extension end and a second extension end, the first and second extension ends are respectively movably inserted into the first and second seat parts, and the first seal is provided on the first base part opposite to the first seal part; On one side of the first space, two ends of a first elastic element abut against the first base of the first rod body and the inner wall surface of the first valve body, respectively. The water-cooled pump structure with a check valve according to claim 6, wherein the first water outlet of the first pump unit corresponds to the first space, and the first water inlet portion corresponds to the first space. Two spaces. The water-cooled pump structure with a check valve according to claim 1, wherein the second check valve further has a second valve body, and the second valve body has a third space and a fourth space inside, The third space has a third seat portion, the fourth space has a fourth seat portion, a second rod body has a second base portion and a second seal, and two ends of the second rod body extend a third An extension end and a fourth extension end, the third and fourth extension ends are respectively axially movably inserted into the third and fourth seat parts, and the second seal is provided on the second base part opposite to the first On one side of the three spaces, two ends of a second elastic element abut against the second base of the second rod body and the inner wall surface of the second valve body, respectively. The water-cooled pump structure with a check valve according to claim 8, wherein the second water outlet of the second pump unit corresponds to the third space, and the second water inlet portion communicates with the first space. Four spaces. A water-cooled module includes:
A first pump unit has a first pump casing forming a first pump chamber, the first pump casing has a first water inlet and a first water outlet, and the first pump chamber is Communicating with the first water inlet and the first water outlet;
A first check valve corresponding to the first water outlet;
A second pump unit has a second pump casing forming a second pump chamber. The second pump casing has a second water inlet and a second water outlet. The second pump chamber is Communicating with the second water inlet and the second water outlet;
A second check valve, which is correspondingly connected to the second water outlet;
A first connector group has a first water inlet portion, a second water inlet portion, and a first water outlet portion. The first water inlet portion is correspondingly connected to the first check valve, and the second water inlet portion is correspondingly connected. The second check valve;
A second connector group has a third water inlet portion, a second water outlet portion, and a third water outlet portion. The second water outlet portion is correspondingly connected to the first water inlet, and the third water outlet portion is correspondingly connected to the second water inlet. Spout
A pipe body group has a first pipe body and a second pipe body. One end of the first pipe body corresponds to the first water outlet, and one end of the second pipe body corresponds to the third inlet. A water part; and a heat dissipation unit having an inlet and an outlet corresponding to the other end of the first pipe body, the outlet corresponding to the other end of the second pipe body, the A cooling chamber is formed inside the heat dissipation unit for a cooling liquid to circulate, and the circulation chamber is in communication with the inlet and the outlet. The water cooling module according to claim 10, wherein the first pump unit has a first communication pipe and a second communication pipe, and two ends of the first communication pipe are respectively connected to the first backstop. A valve and a first water inlet, and two ends of the second communication pipe are respectively connected to the first water inlet and the second water outlet. The water cooling module according to claim 10, wherein the second pump unit has a third communication pipe and a fourth communication pipe, and two ends of the third communication pipe are respectively connected to the second check valve and The second water inlet part, two ends of the fourth communication pipe are respectively connected to the second water inlet and the third water outlet part. The water cooling module according to claim 10, wherein the first check valve further has a first valve body, the first valve body has a first space and a second space inside, and the first space has a A first base portion, the second space has a second base portion, a first rod body has a first base portion and a first seal, and the first rod body extends at both ends of a first extension end and a second Extension ends, the first and second extension ends are respectively axially movably inserted into the first and second seat portions, and the first seal is provided on one side of the first base portion opposite to the first space Both ends of a first elastic element abut against the first base of the first rod body and the inner wall surface of the first valve body, respectively. The water cooling module according to claim 13, wherein the first water outlet of the first pump unit corresponds to the first space, and the first water inlet portion corresponds to the second space. The water cooling module according to claim 10, wherein the second check valve further has a second valve body, the second valve body has a third space and a fourth space inside, and the third space has a A third seat portion, the fourth space having a fourth seat portion, a second rod body having a second base portion and a second sealing member, both ends of the second rod body extending a third extension end and a fourth An extension end, the third and fourth extension ends are respectively movably inserted into the third and fourth seat parts, and the second seal is provided on one side of the second base part opposite to the third space, Two ends of a second elastic element abut against the second base of the second rod body and the inner wall surface of the second valve body, respectively. The water cooling module according to claim 15, wherein the second water outlet of the second pump unit corresponds to the third space, and the second water inlet portion corresponds to the fourth space. The water cooling module according to claim 10 further has a water storage tank, one side of the water storage tank is correspondingly connected to the pipe body group, and the other side of the water storage tank is connected to the inlet of the heat dissipation unit and The outlets are connected accordingly.