BRIEF DESCRIPTION OF THE DRAWINGS
Many aspects of the present apparatus and method can be better understood with reference to the following drawings. The components in the drawings are not necessarily drawn to scale, the emphasis instead being placed upon clearly illustrating the principles of the present apparatus and method. Moreover, in the drawings, like reference numerals designate corresponding parts throughout the several views.
FIG. 1 is a longitudinally cross-sectional view of a heat pipe in accordance with the present invention;
FIG. 2 is a transversely cross-sectional view of the heat pipe of FIG. 1;
FIG. 3 is a first sample of a foil used to form a capillary wick arranged in the heat pipe of FIG. 1;
FIG. 4 is a second sample of a foil used to form the capillary wick arranged in the heat pipe of FIG. 1;
FIG. 5 shows three cross-sectional views that the foils can be shaped;
FIG. 6 is a third sample of a foil used to form the capillary wick arranged in the heat pipe of FIG. 1; and
FIG. 7 is a fourth sample of a foil used to form the capillary wick arranged in the heat pipe of FIG. 1.
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 illustrates a heat pipe in accordance with the present invention. The heat pipe comprises a casing 100 and a capillary wick 200 arranged on an inner wall of the casing 100. A column-shaped vapor passage 300 is enclosed by an inner surface of the capillary wick 200 and located in a center of the casing 100. The casing 100 comprises an evaporating section 400 at an end thereof, a condensing section 600 at an opposite end thereof, and an adiabatic section 500 located between the evaporating section 400 and the condensing section 600. The casing 100 has a column-shaped configuration and typically is made of highly thermally conductive materials such as copper or copper alloys. The casing 100 is filled with a working fluid (not shown) therein, which acts as a heat carrier for carrying thermal energy from the evaporating section 400 toward the condensing section 600 via the vapor passage 300 when undergoing a phase transition from liquid state to vaporous state. In more detail, heat that needs to be dissipated is transferred firstly to the evaporating section 400 of the casing 100 to cause the working fluid to evaporate. Then, the heat is carried by the working fluid in the form of vapor to the condensing section 600 where the heat is released to ambient environment via fins (not shown) attached to the condensing section 600; thus, the working fluid condenses into liquid. The condensed liquid is then brought back, via the capillary wick 200, to the evaporating section 400 where it is again available for evaporation.
The capillary wick 200 has a multi-channel structure along a longitudinal direction of the casing 100. The capillary wick 200 comprises multiple foils stacked together along a radial direction of the casing 100. An outer foil engages an inner surface of the casing 100. Referring to FIG. 2, along the radial direction of the casing 100, the capillary wick 200 has a beehive-shaped structure with a high pore ratio. In the present invention, the foils preferably are metal foils.
Referring to FIG. 3, a first sample of a foil 210 for forming the capillary wick 200 is shown. The foil 210 is formed to have a serrated profile. A plurality of channels 215 is formed by the foil 210 in upper and lower surfaces thereof. When a number of the foil 210 is stacked together radially on the inner surface of the casing 100 to form the capillary wick 200, the channels 215 form the multi-channel structure of the capillary wick 200 for drawing liquid from the condensing section 600 to the evaporating section 400. Referring to FIG. 4, a second sample of a foil 230 for forming the capillary wick 200 is shown. A main difference between the first and second foils 210, 230 is in that the second foil 230 defines a plurality of pores 214 therein, but the first foil 210 does not have any pore therein. When a number of the foil 230 is stacked together radially on the inner surface of the casing 100 to form the capillary wick 200, not only the channels 215 but also the pores 214 form the multi-channel structure of the capillary wick 200 for drawing the condensed liquid from the condensing section 600 back to the evaporating section 400. The multi-channels constructed by the second sample of foil 230 are labyrinthian, in comparison with the multi-channels constructed by the first sample of foil 210, whereby the condensed liquid can take more paths to return to the evaporating section 400 from the condensing section 600 when the capillary wick 200 is formed by the second foil 213. Accordingly, the second sample of foil 230 can more effectively prevent and solve the problem of dry out of the heat pipe in comparison with the first sample of foil 210. The dry out problem is that the condensed liquid cannot be timely drawn back to the evaporating section 400 from the condensing section 600 for a next thermal circulation.
FIGS. 5 (a)-(c) illustrate cross-sectional views of three profiles that the foil can take. FIG. 5(a) shows the serrated profile like that shown in FIGS. 3 and 4. FIG. 5(b) shows that the profile has a wave-like shape. FIG. 5(c) shows that the profile has a beehive-like shape.
Referring to FIG. 6, a third sample of a foil 250 for forming the capillary wick 200 is shown. The foil 250 comprises a plurality of rectangular protruding portions 256 extending from a surface of a body (not labeled) of the foil 250. Each of the protruding portions 256 has only one side connecting with the body (not labeled) of the foil 250. A plurality of rectangular pores 252 is defined in the body of the foil 250 below the protruding portions 256, respectively. The protruding portions 256 are arranged in a matrix so that a plurality of perpendicular micro-channels 280 is formed between the protruding portions 256. The multi-channel structure of the capillary wick 200 can be achieved by the micro-channels 280 of the foil 250 and the rectangular pores 252. Each of the rectangular pores 252 is communicated with corresponding micro-channels 280 through three sides of a space between the protruding portion 256 and the rectangular pore 252, whereby the condensed liquid can flow through not only the micro-channels 280 but also the rectangular pores 252 to reach the evaporating section 400 from the condensing section 600 of the heat pipe.
Referring to FIG. 7, a fourth sample of a foil 270 for forming the capillary wick 200 is shown. The foil 270 comprises a plurality of hollow cylinders 272 extending upwardly from a body (not labeled) of the foil 270. Each hollow cylinder 272 defines a round pore 274 in a center of the cylinder 272. The hollow cylinders 272 are arranged on the body of the foil 270 in a matrix. A plurality of perpendicular micro-channels 280 is formed between the hollow cylinders 272. The multi-channel structure of the capillary wick 200 can be achieved by the micro-channels 280 between the hollow cylinders 272 of the foil 270 and the round pores 274 defined in the hollow cylinders 272.
In practice, the capillary wick 200 can be made by the foils 210, 230, 250, 270 individually, or any combination thereof. Furthermore, a flat foil (not shown) can be interposed between any two shaped foils 210, 230, 250, 270.
Size of the micro-channels of the capillary wick 200 can be accurately controlled by controlling shapes, sizes and stacked density of the foils in manufacturing the capillary wick 200 so as to achieve an optimal capillary pressure. Generally, the more foils that the capillary wick 200 contains, the larger capillary pressure the capillary wick 200 can generate; nevertheless, by modulating the sizes of the channels 215, 280 and the pores 214, 252, 274, the capillary pressure and the heat transmission of the working fluid of the heat pipe at the evaporating section 400 and the condensing section 600 can be adjusted to be optimal for the specific application.
In the present invention, the heat pipe with the capillary wick 200 can be manufactured by using the method as mentioned below. First of all, the foils 210, 230, 250, 270 are wrapped around a mandrel (not shown). The mandrel is used to hold the foils 210, 230, 250, 270 in place. Then, the mandrel is inserted into a hollow metal tube (not shown) for forming the casing 100, whereby the wrapped foils 210, 230, 250, 270 are compressed between the mandrel and an inner surface of the metal tube. The hollow metal tube has one end being sealed. Next, the metal tube with the mandrel and the wrapped foils is placed into an oven and is heated under a high temperature to cause the foils to be sintered to the hollow metal tube. After this sintering step, the mandrel is drawn out of the hollow metal tube and a working fluid such as water, alcohol, methanol, or the like, is injected into the hollow metal tube through an open end of the hollow metal tube. Finally, the hollow metal tube is vacuumed and the open end of the hollow metal tube is hermetically sealed so as to form the heat pipe with the powder wick 200 arranged therein.
It is to be understood, however, that even though numerous characteristics and advantages of the present invention have been set forth in the foregoing description, together with details of the structure and function of the invention, the disclosure is illustrative only, and changes may be made in detail, especially in matters of shape, size, and arrangement of parts within the principles of the invention to the full extent indicated by the broad general meaning of the terms in which the appended claims are expressed.
Patent Application
20070240857
