This application claims benefit of Japanese Patent Application No. 2007-061507 filed on Mar. 12, 2007, which is hereby incorporated in its entirety by reference.
1. Field of the Invention
The present invention relates to a thin liquid cooling (water cooling) system, and particularly, to a liquid cooling system that is suitable to be used for a notebook computer having a plurality of heat-generating elements (heat-generating sources).
2. Description of the Related Art
Recent notebook computers have a plurality of heat-generating elements, such as a GPU and a chip set as well as a CPU. How to effectively cool the plurality of heat-generating elements becomes a technical object for the computers. Further, in a notebook computer in which the storage space for components is limited, as is shown, for example, in Japanese Unexamined Patent Application Publication Nos. 2005-166030, 2003-324174, 2002-94277, and the like, a liquid cooling system is needed that is thin and which is highly unitary property.
However, a conventional liquid cooling system needs tubes in order to connect elements to one another because a pump, a heat-absorbing unit, a heat-radiating unit (radiator), and the like are provided independently. Therefore, the system lacks in integrity (unit property), has a large amount of evaporation in coolant and has a problem even in assembling performance. Further, in a notebook computer in which a plurality of heat-generating elements exist, a heat-radiating structure that can radiate heat more efficiently is desired.
A liquid cooling system includes a heat-radiating sheet having a pair of heat-conductive metal plates that are superimposed on each other, and having a circulating flow passage between the pair of heat-conductive metal plates. A plurality of heat-receiving areas are partitioned on the heat-radiating sheet. A plurality of heat-generating elements are installed on each of the heat-receiving areas via a heat spreader made of a heat-conductive material. An inlet hole and an outlet hole are opened to the surface of the heat-radiating sheet and located at both ends of the circulating flow passage. A pump has a discharge port and a suction port that communicate with the inlet hole and the outlet hole, and is installed on the heat-radiating sheet. A radiator continuous with the circulating flow passage of the heat-radiating sheet.
As shown in
The heat-radiating sheet 10 is composed of a pair of heat-conductive metal plates 10U and 10L that are superimposed on each other, and three planar rectangular heat-receiving areas A, B, and C are set on the sheet 10 by facing slits (easily deformable portion) 10a. On the face of the lower heat-conductive metal plate 10L opposite the upper heat-conductive substrate 10U, the CPU 101, GPU 102, and chip set 103 that are located on the heat-receiving areas A, B, and C, respectively, are mounted (contacted) via heat spreaders 101H, 102H, and 103H, respectively.
The heat-conductive metal plates 10U and 10L of the heat-radiating sheet 10 are preferably made of a metallic material that contains SUS, copper, or aluminum as its main constituent, and the lower heat-conductive metal plate 10L is formed with a flow passage recess 11a that constitutes a circulating flow passage 11. The depth of the flow-passage recess 11a is, for example, around 0.5 mm.
A flow passage cutoff protrusion 11b is formed within the flow passage recess 11a (circulating flow passage 11), and portions in front of or behind the flow passage cutoff protrusion 11b constitute a flow passage starting end 11c and a flow passage terminating end 11d. The flow passage starting end 11c communicates with a heat-absorbing outgoing flow passage 11e that runs in order of the heat-receiving areas C, B, and A, a heat-absorbing folded-back flow passage 11f, and a heat-absorbing incoming flow passage 11g that runs in order of the heat-receiving areas A, B, and C, leads to an inflow end 11h extending to the radiator 40, and is then connected with the flow passage terminating end 11d from a discharge end 11i extending from the radiator 40. Although the flow passages are drawn simply, they can be suitably made to meander so as to increase flow passage length.
In the heat-conductive metal plate 10U, an inlet projection (inlet hole) 12 and an outlet projection (outlet hole) 13 that communicates with the circulating flow passage 11 are formed so as to project in correspondence with the flow passage starting end 11c and the flow passage terminating end 11d, and an outlet projection (outlet hole) 14 and an inlet projection (inlet hole) 15 are formed in correspondence with the radiator inflow end 11h and the radiator discharge end 11i. The inlet projection 12 and the outlet projection 13 communicate with and fit into a discharge port (hole) 34 and a suction port (hole) 35 of the piezoelectric pump 20, respectively.
The piezoelectric pump 20 is set on the upper heat-conductive substrate 10U of the heat-radiating sheet 10. That is, the piezoelectric pump 20 is located on any one of the surface and back of the heat-radiating sheet 10, and the CPU 101, GPU 102, and the chip set 103 are located on the other face thereof. According to this arrangement, planar superimposition with a cooling fan can be permitted, cooling efficiency can be improved, and the planar size of the whole liquid cooling system 100 can be suppressed. Further, if the piezoelectric pump 20 and the radiator 40 are arranged on the lower side in
Although the configuration of the pump (piezoelectric pump) 20 does not matter in the invention, the piezoelectric pump 20 of the embodiment will be described with reference to
The discharge port 34 and the suction port 35 are bored in the lower housing 21 so as to be orthogonal to a plate thickness plane of the housing and parallel to each other. A piezoelectric vibrator (diaphragm) 28 is liquid-tightly sandwiched and supported between the upper housing 21 and the lower housing 22 via the O ring 29, and a pump chamber P is formed between the piezoelectric vibrator 28 and the lower housing 21. An atmospheric chamber P is formed between the piezoelectric vibrator 28 and the upper housing 22.
The piezoelectric vibrator 28 is a unimorph vibrator having a central shim 28a, and a piezoelectric body 28b stacked on one (upper face of
The discharge port 34 and suction port 35 of the lower housing 21 are respectively provided with check valves (umbrella) 32 and 33. The check valve 32 is a suction-side check valve that allows flow of fluid from the inlet port 35 to the pump chamber P, and does not allow flow of the fluid in a direction reverse thereto, and the check valve 33 is a discharge-side check valve that allows flow of the fluid from the pump chamber P to the outlet port 34, and does not allow flow of the fluid in a direction reverse thereto.
The check valves 32 and 33 have the same form, and are constructed by mounting umbrellas 32b and 33b made of an elastic material on perforated substrates 32a and 33a bonded and fixed to flow passages. Such check valves (umbrellas) themselves are widely known.
In the above piezoelectric pump 20, if the piezoelectric vibrator 28 elastically deform (vibrates) in a vertical direction in the direction of the diameter, the suction-side check valve 32 is opened and the discharge-side check valve 33 is closed, in a stroke where the volume of the pump chamber P increases. Therefore, liquid flows into the pump chamber P from the suction port 35 (outlet projection 13 of the heat-radiating sheet 10) (
The radiator 40 is obtained by connecting the outlet projection (outlet hole) 14 and the inlet projection (inlet hole) 15 of the heat-radiating sheet 10 directly (without via a tube). As shown in
Each flow passage unit 41 is constituted by a pair of flow passage plates 42U and 42L that are superimposed on and coupled with each other. The flow passage plates 42U and 42L are constituted from, for example, press-molding articles made of a metallic material (brazing sheet) that is excellent in heat-conductivity, and have a symmetrical shape (the same single body shape) with respect to a superimposed face (stacked face).
The above-described flow passage plates 42U and 42L are superimposed on each other such that the flow passage recesses 46 face outward in directions opposite to each other, and their joining faces 45 are joined together by, for example, brazing. Then, a flat U-shaped coolant flow passage 11X is formed by the upper and lower U-shaped flow passage recesses 46 that protrudes in the directions opposite to each other. Further, the spacers 47S (48S) of the upper and lower flow passage units 41 abut on each other, whereby the inlet holes 47 of the upper and lower flow passage units 41 communicates, and the outlet holes 47 thereof communicate with each other. Between the superimposed flow passage units 41, a cooling air passage space S (
The outlet projection (outlet hole) 14 and inlet projection (inlet hole) 15 that are formed in the heat-conductive metal plate 10U fit into the inlet hole 47 and outlet hole 48, respectively, of the lowermost flow passage unit 41, and a plurality of layers of radiator flow passages are formed from the radiator inflow end 11h to the radiator discharge end 11i.
The heat-radiating sheet 10 and the radiator 40 have a planar U-shaped space as a whole, and the cooling fan (sirocco fan) 50 is disposed within this U-shaped space. A blow-off direction W (
In the liquid cooling system 100 having the above configuration, the heat-receiving areas A, B, and C are defined on the single (made of a continuous metallic material) heat-radiating sheet 10, and the CPU 101 (heat sink 101H), the GPU 102 (heat sink 102H), and the chip set 103 (heat sink 103H) are mounted on the heat-receiving areas A, B, and C, respectively. Further, since the piezoelectric pump 20 and the radiator 40 are coupled together in the heat-radiating sheet 10, all circulating flow passages are formed without using a flexible tube. Since the heat-receiving areas A, B, and C is partitioned by the facing slits (easily deformable portions) 10a, even if a height difference is between CPU 101 (heat sink 101H), the GPU 102 (heat sink 102H), and the chip set 103 (heat sink 103H), each heat-receiving area can be deformed flexibly so as to follow the height difference, and thermal coupling to the flat face of each heat-generating elements can be made easy.
The liquid discharged from the discharge port 34 of the piezoelectric pump 20 enters the circulating flow passage 11 (flow passage starting end 11c) from the inlet projection 12 of the heat-conductive metal plate 10U, then flows through the heat-absorbing flow passage 11e, 11f, and 11g in the heat-receiving areas A, B, and C, thereby absorbing heat from the CPU 101, the GPU 102, and the chipset 103, and then reaches the outlet projection 14 of the heat-radiating sheet 10 at the radiator inflow end 11h. After the liquid that has reached the outlet projection 14 enters the cooling flow passage 11X from the inlet hole 47 of each flow passage unit 41 of the radiator 40 and leaves the outlet hole 48, the liquid is discharged to the radiator discharge end 11i from the inlet projection 15, and returns to the flow passage terminating end 11d. The liquid that has reached the flow passage terminating end 11d returns to the inside of the piezoelectric pump 20 from the inlet projection 12, and thereafter, repeats the same circulation. The liquid that passes through the cooling flow passage 11X within the radiator 40 is more sufficiently cooled by the cooling wind from the cooling fan (sirocco fan) 50.
In the above embodiment, easily deformable portions are formed in the heat-radiating sheet 10 by the facing slits (easily deformable portions) 10a. However, the easily deformable portions may be formed by thin-walled portions. Further, in the illustrated example, the facing slits (easily deformable portions) 10a are formed in both the heat-conductive metal plates 10U and 10L, the facing slits (easily deformable portions) 10a may be formed only at one of them.
Number | Date | Country | Kind |
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2007-061507 | Mar 2007 | JP | national |