The invention is relative to a heat pipe, especially relative to a heat pipe utilizing vapor pressure difference to drive working fluids.
A heat pipe of prior art is mainly composed of a closed metal tube, a wick structure and heat transferring fluid filled in the metal tube. An appropriate vacuum degree in the metal tube is maintained for reducing the starting temperature difference of heat pipe. The evaporator of the heat pipe is located at the heat source, and the fluid in the metal tube absorbing the heat generated by the heat source can be evaporated to a vapor. The vapor is flowed to the condenser of the heat pipe according to the difference of the vapor pressure. Then the vapor will be condensed as liquid fluids at the condenser of the heat pipe by heat dissipation. The fluids will be flowed back to the evaporator of the heat pipe according to the wick structure. Thus, the heat of heat pipe can be transferred efficiently by the above structure.
Since the heat pipe structure is simple and has a high conductivity, low thermal resistance, the heat pipe had been applied in electronic industry or other heat dissipation fields. Because the electronic devices are developed as the portable electronics applications, lighter and thinner device, 4K video, 4G transmission, and high added functionality. The heat generated by the electronic device is getting higher according to advance of the electronic devices. The heat pipe of the prior art can not satisfy the demand for dissipating a lot of heat of heat and high heat flux. Thus the performance of the heat pipe should be improved. For instance, the manufacturing method of the wick structure should be improved, and the composite wick structure for enhancing the capillary force of the wick structure is utilized. However, these improving methods require complicated procedures and lengthy time, and the configuration of the heat pipe is still too complex to be taking into account the costs and effects of the heat pipe.
Furthermore, when the heat pipe of the prior art is in operation, the direction of the vapor is opposite to the direction of the working fluids. The vapor and the working fluids are not separated. The working fluids should be overcome the resistance of the vapor flow and then returned to the evaporator of the heat pipe for next cycle. The heat pipe should meet the capillary limitation for the continuously dynamic cycle (the internal capillary force must be greater than total force of the vapor pressure, and other fluid reflux resistance and gravity forces).
Therefore, it is an important subject to provide a simple structure heat pipe provided for increasing the heat transferring capacity, high-efficient heat dissipation and high heat flux of the electronic device.
In view of foregoing subject, an objective of the present invention is to provide a heat pipe with simple structure for increasing heat flux and effectively solving the request of the high-efficient heat dissipation and high heat flux.
For achieving the above objective, a heat pipe according to the present invention includes a first pipe and at least one second pipe. The first pipe is formed with an enclosed space. The second pipe is disposed in the enclosed space. No wick structure is disposed at an interior of the second pipe. No wick structure is disposed between the first pipe and the second pipe.
In one embodiment, the second pipe includes two ends along an axial direction, and a middle part between the two ends. A cross-sectional area of one of the two ends is larger than that of the middle part.
In one embodiment, the second pipe comprises two ends along an axial direction, and a middle part between the two ends. A cross-sectional area of one of the two ends is smaller than that of the middle part.
For achieving the above objective, a heat pipe according to present invention includes a first pipe and at least one second pipe. The first pipe is formed with an enclosed space. No wick structure is disposed at an inner sidewall of the first pipe. At least one second pipe disposed in the enclosed space. No wick structure disposed at an exterior sidewall of the second pipe.
In one embodiment, the second pipe includes two ends along an axial direction, and a middle part between the two ends. A cross-sectional area of one of the two ends is larger than that of the middle part.
In one embodiment, the second pipe includes two ends along an axial direction, and a middle part between the two ends. A cross-sectional area of one of the two ends is smaller than that of the middle part.
For achieving the above objective, a heat pipe according to present invention includes a first pipe. The first pipe is formed with an enclosed space and no wick structure disposed at an inner sidewall of the first pipe. A part of sidewall of the first pipe is deformed to define a first section and a second section. The second section includes a first opening and a second opening. The first opening and the second opening are communicated with the first section, respectively.
In one embodiment, the second section includes two ends along an axial direction, and a middle part between the two ends. A cross-sectional area of one of the two ends is larger than that of the middle part.
In one embodiment, the second section includes two ends along an axial direction, and a middle part between the two ends. A cross-section area of one of the two ends is smaller than that of the middle part.
In one embodiment, a size of the second section is smaller than that of the first section.
According to above, the heat pipe of the present invention includes a first pipe and a second pipe disposed in the first pipe. Due to simple structure for easy manufacturing, the quality and the yield of the manufacturing of the heat pipe can be increased and the cost can be decreased. Additionally, the heat pipe of the present invention with inner pipe and outer pipe can improve the efficiency of the liquid-gas cycle in the heat pipe and the heat conducting ability of the heat pipe. The heat pipe of the present invention is especially for avoiding the transient heat shock and providing a solution for high-efficient heat dissipation and high heat flux.
The invention will become more fully understood from the detailed description and accompanying drawings, which are given for illustration only, and thus are not limitative of the present invention, and wherein:
A heat pipe according to a preferred embodiment of the present invention will be apparent from the following detailed description, which proceeds with reference to the accompanying drawings, wherein the same references relate to the same elements.
In the embodiment, the first pipe 1 is an elliptic cylindrical pipe with a thin wall. A section taken along a radial direction of the first pipe is a uniform section. The first pipe 1 can be made of Cu, Ag, Al, an alloy combined by those or other metals with good heat efficiency. In actual application, except for the second pipe 2 disposed in the first pipe 1, a plurality of working fluids (not shown) is also disposed in the first pipe 1. The working fluids can be a fluid for easily evaporated by heat. The working fluids can be inorganic compounds, alcohols, ketones, liquid metal, Freons, organic compounds or mixtures thereof. Furthermore, the shape, the size of the first pipe 1 is not limited to that shown in figures. For instance, the first pipe 1 can be a cylindrical tube or a rectangular tube. The ends of the first pipe 1 are determined by environment, space, heat conductivity and temperature.
Referring to
In actual application, an end located at a heat source is the evaporating part E. Another end far away form the heat source is the condensing part C of the heat pipe H. In the heat dissipation process, the working fluids closer to the evaporating part E is evaporated by the heat of the heat source to a vapor. The vapor is moved to the condensing part C of the first pipe. Then the vapor can be condensed as the working fluids. Thus, the evaporating part E is a high pressure area and the condensing part C is a low pressure area. The vapor is driven by the vapor pressure difference in the first pipe 1 from the evaporating part E through the heat insulation part A to the condensing part C. The condensed working fluids are driven in the second pipe 2 to the evaporating part E by the vapor pressure difference. In other words, the working fluids are evaporated to a vapor by absorbing the heat generated by the heat source. The vapor is driven to the condensing part C of the heat pipe H by the vapor pressure difference. The vapor is condensed to liquid working fluids at the condensing part C by heat dissipation. Thus, the heat can be dissipated by this continuously liquid-gas cycle in the pipe H of the embodiment.
Additionally, because no wick structure is disposed between the first pipe 1 and the second pipe 2, it means that no wick structure is disposed at the interior sidewall of the first pipe 1 and the exterior sidewall of the second pipe 2. Thus, the liquid-gas cycle of the heat pipe H can be improved to increase the heat conducting ability of the heat pipe H. Furthermore, in the heat pipe H, the working fluids are driven by the vapor pressure to flow back and with less anti-gravity problem. Preferably, due to simple structure of the heat pipe H for easy manufacturing, the quality and the yield of the manufacturing can be increased and the cost can be decreased.
The two ends 21b, 22b of the second pipe 2b are not limited to above descriptions and drawings. In the other embodiment, the two ends 21b, 22b can respectively be a diverging configuration and a converging configuration. It just depends on the requests for applications.
In details, the second section 2d includes a first opening 24d and a second opening 25d. The first opening 24d and the second opening 25d are communicated with the first section, respectively. Thus, the heat pipe H4 can include the same heat dissipation system of the heat pipe H of the above embodiment. The working fluids are driven by vapor pressure to flow back in the second section 2d and the first section 10d for heat dissipation.
Furthermore, the size of the second section 2d is smaller than that of the first section 10d. It means that the size of the liquid channel (the second section 2d) of the heat pipe H4 is smaller than that of the vapor channel (the first section 1d). Thus, a better heat dissipation efficiency of the heat pipe H4 can be achieved. On the other side, the heat pipe H4 in the embodiment is formed by pressing the first pipe 1d to form the channels for the working fluids and the liquid-gas cycle. The process can be simplified and prevent the shift problem caused by assembling a plurality of pipes in one large pipe.
Additionally, the same parts of the heat pipe H4 and the heat pipe H2 of above embodiment are as follows. The second section 2d includes two ends 21d, 22d along the axial direction D1 and a middle part 23d between the two ends 21d, 22d. The end 21d includes a converging configuration (not shown). Thus, the cross-sectional area of the end 21d is smaller than that of the middle part 23d. The end 22d includes a diverging configuration (not shown). Thus, the cross-sectional area of the end 23d is larger than that of the middle part 23d. According to the configuration of heat pipe H4, the flowing back ability of the second section 2d can be improved. Thus, the heat conducting efficiency of the vapor of the first pipe 10d and the second pipe 2d can be improved.
In summary, the heat pipe of the present invention includes a first pipe and a second pipe disposed in the first pipe. Due to simple structure for easy manufacturing, the quality and the yield of the manufacturing of the heat pipe can be increased and the cost can be decreased. Additionally, the heat pipe of the present invention with inner pipe and outer pipe can improve the efficiency of the liquid-gas cycle in the heat pipe and the heat conducting ability of the heat pipe. The heat pipe of the present invention is especially for avoiding the transient heat shock and providing a solution for dissipating a lot of heat and high heat flux.
Although the invention has been described with reference to specific embodiments, this description is not meant to be construed in a limiting sense. Various modifications of the disclosed embodiments, as well as alternative embodiments, will be apparent to persons skilled in the art. It is, therefore, contemplated that the appended claims will cover all modifications that fall within the true scope of the invention.
Number | Date | Country | Kind |
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2015 1 0011351 | Jan 2015 | CN | national |
This application is a Divisional of co-pending application Ser. No. 14/704,218 filed on May 5, 2015, which claims priority to 201510011351.7 filed in People's Republic of China on Jan. 9, 2015, the entire contents of which are hereby incorporated by reference.
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Number | Date | Country | |
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20180038659 A1 | Feb 2018 | US |
Number | Date | Country | |
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Parent | 14704218 | May 2015 | US |
Child | 15783300 | US |