DE20212754U1 - Coolant heat dissipation device - Google Patents

Description

Coolant heat dissipation device

The invention relates to a cooling liquid heat dissipation device, and more particularly to a heat dissipation device that enables heat to be dissipated from a central processing unit using a cooling liquid flow.

As the computer industry has advanced, the processing speed of the computer, and particularly that of its central processing unit, has become increasingly faster. This increase in processing speed increases the amount of heat radiated by the central processing unit. In order to effectively dissipate this significant amount of heat and maintain normal operating conditions for the central processing unit, many designs of fans and heat dissipation devices with increased heat dissipation surface areas have been developed.

Fig. 1 is a perspective view explaining the conventional structure of a heat dissipation device 10a for a central processing unit, which heat dissipation device 10a has a plurality of heat dissipation fins 11a to increase the heat dissipation surface area. The heat dissipation device 10a is fixedly arranged on a central processing unit 30a, and further a fan 20a is mounted above the heat dissipation device 10a to ensure effective heat dissipation from the central processing unit 30a and to maintain normal operating conditions.

In the conventional heat dissipation device as described above, the heat dissipation

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achieved primarily by heat conduction, which is far from insufficient considering the considerable amount of heat radiated from the central processing unit. Consequently, with the continuous increase in the processing speed of the central processing unit, the limited heat dissipation capacity of the conventional heat dissipation device and the fan is a bottleneck.

It is therefore an object of the invention to provide a cooling liquid heat dissipation device that utilizes the combination of a recirculating flow of cooling liquid and an air flow to achieve optimal heat dissipation from a central processing unit.

It is another object of the invention to provide a cooling liquid heat dissipation device in which a single drive element is used to simultaneously drive the air flow and the cooling liquid flow, thereby reducing the space requirement and the manufacturing cost.

To achieve the above and other objects, a cooling liquid heat dissipation device according to the invention comprises a base having an internal accommodation space containing a cooling liquid, the accommodation space being accessible via a pair of inlet/outlet openings. A fan is mounted to the base and has a drive rotor. A liquid pump associated with the drive rotor of the fan is arranged in the accommodation space of the base. A magnetic force-based connection unit further connects the rotor of the fan to the liquid pump. The pair of inlet/outlet openings of the base are connected via a liquid circulation line.

The invention will now be described in detail using preferred embodiments of the invention with reference to the accompanying drawings.

Fig.l is a perspective view schematically illustrating a conventional heat dissipation device for a central processing unit according to the prior art.

Fig.2 is an exploded view schematically illustrating a heat dissipation device according to a first embodiment of the invention.

Fig.3 shows a perspective view of the assembled heat dissipation device according to the first embodiment of the invention.

Fig.4 shows a sectional view of the heat dissipation device according to the first embodiment of the invention.

Fig.5 is a sectional view schematically explaining the mechanism of the heat dissipation device according to the first embodiment of the invention.

Fig.6-8 show various perspective views illustrating other embodiments of the heat dissipation device according to the invention.

In the following description, unless otherwise stated, like reference numerals designate like parts and sections.

With reference to Fig.2, Fig.3 and Fig.4, the invention provides a cooling liquid heat dissipation device comprising a base 10, a fan 20, a water pump 30 and a water circulation pipe 40. The base is made of a metal with good thermal conductivity and has a receiving space 11 which has an inlet/outlet opening 12 and an inlet/outlet opening 13 on opposite sides, respectively. The receiving space serves to receive cooling water and is provided inside with

a separating panel 14 which divides the receiving space 11 into appropriate subspaces.

The fan 20 is mounted on a top of the base 10 and is firmly attached by means of, for example, screws 21. The fan 20 is an active element and has a rotor 22 which in turn is driven by electrical energy. The underside of the rotor 22 is provided with a magnet 23 which rotates synchronously with the rotor 22.

The water pump 30 is arranged within the accommodation space 11 of the base 10 under the fan 20 in accordance with the position of the rotor 22. The water pump 30 is provided at its center with a rotary shaft 31 which is rotatably supported on the base 10 to rotate vanes 32 in orbit and generate a cooling water flow. The water pump 30 is further provided with a metal part 33 such as a metal part 34.

an iron plate which can be magnetically attracted by the magnet 23.

The water pump 3 0 is a passive element and is connected to the rotor 22 via a magnetic force-based connection unit, which is realized by means of the magnet 23 and the metal part 33. The water pump 3 0 thus rotates synchronously according to the drive rotation of the rotor 22 of the fan 20.

The top of the base 10 is further provided with a sealing cover 34 which is firmly attached by means of screws 35. A seal 36, such as an O-ring seal, is arranged between the sealing cover 34 and the base 10 in order to ensure a hermetic seal of the top of the base 10.

The water circulation line 40 has a first line device element 41, a second line device element 42, a third line device element 43, a fourth line device element 44 and

a fifth duct member 45. The first duct member 41 is formed from a metal-based material with good thermal conductivity. The first duct member 41 has a first hollow connector 411 which fits into the inlet/outlet opening 13 of the base 10 and is fixedly attached by screws 416 to connect the first duct member 41 to the base 10. The first hollow connector 411 is connected to a plurality of first tubes 412 to which a second hollow connector 413 is further coupled. One side of the second hollow connector 413 is provided with an auxiliary opening 414 which, when not in use, is hermetically sealed by a sealing body 415.

The second conduit element 42 is also formed from a metal-based material with good thermal conductivity and has a plurality of flow channels 421 inside. The second conduit element 42 is connected to the first conduit element 41 via the second hollow connecting piece 413. A seal 426 is arranged between the second conduit element 42 and the second hollow connecting piece 413 of the first conduit element 41. The flow channels 421 of the second conduit element 42 are each associated with the first tubes 412 of the first conduit element 41 and are further connected at an opposite end to a plurality of second tubes 422. One side of the flow channels 421 is further provided with an auxiliary opening 423 which, when not in use, is hermetically sealed by means of a cover 424 and a seal 425. The cover 424, the second line device element 42 and the first line

Device elements 41 are firmly connected to each other by means of screws 427.

The third duct member 43 is also formed of a metal-based material having good thermal conductivity and includes a plurality of third tubes 431 passing through a plurality of thermal convection cooling plates 432. One end of each third tube 431 is coupled to one of the second tubes 422 to connect the third duct member 43 to the second duct member 42.

The fourth duct member 44 is also formed from a metal-based material with good thermal conductivity and has a third hollow connector 441 coupled to the inlet/outlet opening 12 of the base 10. The firm connection of the fourth duct member 44 to the base 10 is also ensured by means of screws 446. The third hollow connector 441 is connected to a plurality of fourth tubes 442, which are further coupled to a fourth hollow connector 443. One side of the fourth hollow connector 443 is provided with an auxiliary opening 444, which, when not in use, is hermetically closed by means of a sealing body 445.

The fifth conduit element 45 is formed from a metal-based material with good thermal conductivity and has a plurality of flow channels 451 inside. The fifth conduit element 45 is coupled to the fourth hollow connector 443 of the fourth conduit element 44, with a seal 456 disposed between the fifth conduit element 45 and the fourth hollow connector 443 of the fourth conduit element 44. The flow channels 451 of the fifth conduit element 45 are associated with a respective one of the

fourth tubes 442 of the fourth piping element and further communicate with a plurality of fifth tubes 452 at an opposite end. One side of the flow channels 451 is further provided with an auxiliary opening 453 which, when not in use, is hermetically closed by a cover 454 and a gasket 455. The cover 454, the fifth piping element 45 and the fourth piping element 44 are fixedly connected to each other by screws 457. Further, another end of each third tube 431 is coupled to one of the fifth tubes. Thus, a cooling liquid heat dissipation device according to the first embodiment of the invention is formed.

As explained in Fig.5 and Fig.6, the base is firmly attached to a central processing unit 51 of a mainboard 5 0. Via the rotation of the water pump 3 0, which is driven synchronously by the fan 2 0, cooling water, which is located within the receiving space 11 of the base 10, flows through the inlet/outlet opening 13.

Thereby, a cooling water flow circuit is realized sequentially through the first piping element 41, the second piping element 42, the third piping element 43, the fourth piping element 44 and the fifth piping element 45 of the water circuit line 40, which is fed back into the base through the other inlet/outlet opening 12.

The heat radiated by the central processing unit 51 during operation is thus dissipated into the base 10 and the water circuit line 40. Through heat conduction of the material of the base 10 and the water circuit line 40, supported by the heat dissipation by means of the cooling water

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flow, the heat is further dissipated to the outside by means of the heat convection cooling plates 432, which have an enlarged heat dissipation surface area. By means of the fan 20, a continuous air flow is also provided via the base 10, the water circuit line 40 and the heat convection cooling plates 432, respectively, in order to achieve optimal heat dissipation.

As described above, the invention therefore uses the combination of air flow and cooling liquid flow to achieve optimum heat dissipation from the central processing unit. Consequently, by using the fan to synchronously drive the rotation of the water pump, the cooling liquid flow can be achieved without the need for a drive source other than the fan, thereby reducing the space requirement and the manufacturing cost.

Furthermore, as shown in Fig.7, in the invention, a plurality of coolant-based heat dissipation devices constructed as already explained may be connected to one another via pipes 60, 61 and 62. As shown in Fig.8, in the invention, the coolant-based heat dissipation device may alternatively be connected to a heat dissipation block 70 and a fan 71 via pipes 63 and 64 and to a data storage device 80 via pipes 65, 66.

In summary, a cooling liquid-based heat dissipation device according to the invention comprises: a base having a receiving space containing cooling liquid therein, the receiving space being accessible via a pair of inlet/outlet openings, a fan mounted on the base and having a drive rotor, a liquid pump arranged within the receiving space of the base associated with the drive rotor of the fan

further comprising a magnetic force-based connection unit connecting the rotor of the fan to the liquid pump, a liquid circulation line through which the pair of inlet/outlet openings of the base are connected, and a heat dissipation device that enables the heat radiated from the central processing unit to be dissipated through
liquid cooling.

Claims (6)

1. A cooling liquid heat dissipation device comprising:
a base ( 10 ) having therein a receiving space ( 11 ) containing cooling liquid, the receiving space ( 11 ) having a pair of inlet/outlet openings ( 12 , 13 ),
a fan ( 20 ) mounted on the base ( 10 ) and having a rotor ( 22 ),
a liquid pump ( 30 ) arranged within the receiving space ( 11 ) of the base ( 10 ) associated with the drive rotor ( 22 ) of the fan ( 20 ),
a magnetic force-based connection unit via which the rotor ( 22 ) of the fan ( 20 ) is connected to the liquid pump ( 30 ), and
a liquid circulation line ( 40 ) connecting the pair of inlet/outlet openings ( 12 , 13 ) of the base ( 10 ). 2. The device according to claim 1, wherein the fan ( 20 ) is mounted on a top of the base ( 10 ) and the liquid pump ( 30 ) is arranged below the fan ( 20 ). 3. The device according to claim 1, wherein the liquid pump ( 30 ) is centrally provided with a rotary shaft ( 31 ) rotatably mounted on the base ( 10 ) for rotating a plurality of vanes ( 32 ) to generate a cooling water flow. 4. The device according to claim 1, wherein the magnetic force-based connection unit comprises a magnet ( 23 ) arranged on the rotor ( 22 ) of the fan ( 20 ) and a metal part ( 33 ) associated with the magnet ( 23 ) which is arranged on the liquid pump ( 30 ). 5. The device of claim 1, wherein the liquid circulation line ( 40 ) further comprises the arrangement of a first line device element ( 41 ), a second line device element ( 42 ), a third line device element ( 43 ), a fourth line device element ( 44 ) and a fifth line device element ( 45 ). 6. Device according to claim 5, wherein the third conduit device element ( 43 ) comprises at least one tube ( 431 ) externally coupled to a thermal convection cooling plate ( 432 ).