The present invention relates to the technical field of heat pipe, and more particularly, to a floating heat pipe assembly and a clamp collar for using therewith.
A heat pipe is a hollow metal pipe, in which an adequate amount of working fluid is filled. The principle for the heat pipe to dissipate heat is the two-phase change of the working fluid in the heat pipe. More specifically, the working fluid absorbs heat from a heat source located corresponding to an evaporator section that is located at an end of the heat pipe, such that the working fluid is finally vaporized and changes from a liquid phase into a vapor phase. The vaporized working fluid diffuses in the heat pipe and carries the absorbed heat through a thermal insulated section to a condenser section located at another end of the heat pipe to achieve the purpose of transferring heat to a remote location relative to the heat source.
The currently available heat pipe is usually used with a heat dissipation unit, such as snap-on fins or aluminum-extruded fins or a heat sink, to form a thermal module, which is mounted in an electronic device, such as a computer, a server, a communication chassis, a mobile phone or a hand-held device, to dissipate heat generated by heat sources on a mother board.
However, the packaged heat sources on the mother board of the electronic device are different in their heights. Therefore, it is very possible a height difference is existed between two heat sources and not all the evaporator sections of some heat pipes in the thermal module can be in flat contact with the heat sources. The heat pipe being forcefully connected to two heat sources having a height difference between them is subjected to the risk of reduced heat transfer efficiency or even malfunction. This is because the hollow pipe of the heat pipe is made of a metal sheet material having the same thickness, that is, the evaporator section, the thermal insulated section and the condenser section of the heat pipe are consistent in their pipe wall thickness. In the event the evaporator section or the condenser section of the heat pipe needs to be adjusted in its height location to cover the height difference between two heat sources and the thermal insulated section of the same pipe wall thickness is flexed or bent for this purpose, a bridging force between the evaporator section and the condenser section tends to pull and push the evaporator and the condenser section and to deform due to inward compression or outward pull the thermal insulated section for transferring the vapor-phase working fluid, which would further result in breaking or separation of the wick structure provided on inner wall surfaces of the heat pipe and accordingly, poor heat transfer efficiency or even malfunction of the heat pipe.
It is therefore tried by the inventor to develop an improved floating heat pipe assembly to overcome the problem in the conventional heat pipe.
A primary object of the present invention is to provide a floating heat pipe assembly, which avoids a floating heat pipe from reduced efficiency of capillary action or malfunction due to a structural deformation of the floating heat pipe caused by a bridging force between two sections of the floating heat pipe having a height difference between them.
Another object of the present invention is to provide a clamp collar for using with a floating heat pipe. The clamp collar is fitted around a flattened section of the floating heat pipe with two elastic clamping sections of the clamp collar clamped on an upper outer side and a lower outer side of the flattened section, so as to hold the flattened section in place from outside of the floating heat pipe and enable the flattened section to resist the bridging force thereat due to a height difference between a front section and a rear section at two opposite ends of the flattened section.
To achieve the above and other objects, the floating heat pipe assembly according to the present invention includes a floating heat pipe and a clamp collar. The floating heat pipe includes a front section and a rear section that respectively have a pipe size, and a flattened section located between the front and the rear section and having a flattened pipe size that is smaller than the pipe sizes of the front and rear sections. The floating heat pipe internally defines a chamber, which extends from the front section through the flattened section to the rear section and has a wick structure and a working fluid provided therein. The clamp collar is fitted on around the flattened section of the floating heat pipe and includes two symmetrically arranged elastic clamping sections and two symmetrically arranged connecting sections. The two elastic clamping sections are clamped on two opposite outer sides of the flattened section, and the two connecting sections are connected to between the two elastic clamping sections.
The two elastic clamping sections are vertically symmetrically arranged at an upper and a lower location and respectively have two connecting ends and an inward protruded middle portion located between the two connecting ends. The middle portions of the two elastic clamping sections are in contact with and pressed against the flattened section of the floating heat pipe. The two connecting sections are laterally symmetrically arranged at a right and a left location and respectively connected at two ends to between the connecting ends of the two elastic clamping sections. And, the two elastic clamping sections and the two connecting sections together define an elastically deformable space in between them.
The elastic clamping sections are respectively concave-shaped or flat-bottomed relative to the flattened section.
The two elastic clamping sections are symmetrically arranged and transversely extended relative to the flattened section and the two connecting sections are symmetrical arranged and vertically extended relative to the flattened section. And, the two elastic clamping sections and the two connecting sections together form a substantially rectangular integral structure.
The two opposite outer sides of the flattened section are an upper outer side and a lower outer side thereof. The floating heat pipe is adjustable at the flattened section for the front section and the rear section to displace to two positions having a height difference between them.
To achieve the above and other objects, the clamp collar according to the present invention is fitted on around a flattened section formed on a local area of a floating heat pipe. The clamp collar includes two elastic clamping sections vertically symmetrically clamped on an upper outer side and a lower outer side of the flattened section and at least one connecting section connected to between the two elastic clamping sections.
The two elastic clamping sections respectively have two connecting ends and an inward protruded middle portion located between the two connecting ends to contact with and press against the flattened section of the floating heat pipe. The at least one connecting section is located between and connected to two connecting ends of the two elastic clamping sections that are located at the same side of the clamp collar. The two elastic clamping sections and the at least one connecting section together define an elastically deformable space in between them.
The two elastic clamping sections are respectively concave-shaped or flat-bottomed relative to the flattened section, and the at least one connecting section is arc-shaped to be concave or convex relative to the flattened section.
In an embodiment, the clamp collar includes two connecting sections, which are laterally symmetrically located between and connected to the connecting ends of the two elastic clamping sections.
The floating heat pipe using the clamp collar has a front section and a rear section located at two opposite ends of the flattened section; and the floating heat pipe is adjustable at the flattened section to displace the front and the rear section to two positions having a height difference between them.
The front section and the rear section of the above floating heat pipe respectively define a pipe size and the flattened section located between the front and the rear section defines a flattened pipe size. The flattened pipe size is smaller than the pipe sizes of the front and rear sections. The floating heat pipe internally defines a chamber, which extends from the front section through the flattened section to the rear section and has a wick structure and a working fluid provided therein.
The structure and the technical means adopted by the present invention to achieve the above and other objects can be best understood by referring to the following detailed description of the preferred embodiments and the accompanying drawings, wherein
The present invention will now be described with some preferred embodiments thereof and by referring to the accompanying drawings. For the purpose of easy to understand, elements that are the same in the preferred embodiments are denoted by the same reference numerals.
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The front section 111 and the rear section 113 respectively have, for example, a round cross section and a pipe size D1, D3. In the illustrated preferred embodiment, the pipe sizes D1, D3 are diameters of the round cross sections of the front section 111 and the rear section 113, respectively. The pipe sizes D1 and D3 can be the same as or different from each other without being particularly limited. That is, the pipe size D1 of the front section 111 can be larger or equal to the pipe size D3 of the rear section 113. In addition, the front section 111 and the rear section 113 respectively have another closed end that are located opposite to the flattened section 112 and are two outer most ends of the floating heat pipe 11. It is understood the present invention is not limited thereto. In other operable embodiments, one of the two outer most ends of the floating heat pipe is a closed end while the other one is an open end, and the chamber 114 is communicable with an external chamber, such as the chamber in a vapor chamber or a heat spreader, via the open end.
Further, the flattened section 112 and the front and rear sections 111, 113 are integrally formed. More specifically, the flattened section 112 is formed by pressing a local area of the floating heat pipe 11 from one or two opposite vertical directions. For example, the floating heat pipe 11 can be pressed from an upper or a lower side thereof or from both the upper and lower sides thereof to form the flattened section 112, such that the flattened section 112 is a substantially rectangular structure or a polygonal structure having at least two corresponding sides or surfaces that are arc-shaped or flat-bottomed. The flattened section 112 has two opposite outer sides, which are an upper outer side 1121 and a lower outer side 1122 thereof; and a flattened pipe size D2 defined between the upper outer side 1121 and the lower outer side 1122. The flattened pipe size D2 is smaller than the pipe sizes D1 and D3. That is, the flattened section 112 has an overall thickness smaller than that of the front section 111 and of the rear section 113. Therefore, the floating heat pipe is adjustable at the thinner flattened section 112 to displace the front section 111 and the rear section 113 to two different positions having a height difference between them.
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The two elastic clamping sections 122 and the two connecting sections 123 together form an integral structure. In the illustrated preferred embodiment, both of the elastic clamping sections 122 and the connecting sections 123 are concave in shape relative to the flattened section 112, as shown in
The two elastic clamping sections 122 clamp on the two opposite outer sides of the flattened section 112, and respectively define two connecting ends 1221, 1222. An inward protruded middle portion 1223 of each of the elastic clamping sections 122, i.e. the bottom of the concave elastic clamping section 122, is located in middle between the two connecting ends 1221, 1222; and the inward protruded middle portions 1223 respectively contact with and press against the upper outer side 1121 and the lower outer side 1122 of the flattened section 112. The two connecting sections 123 are respectively located between and connected to the connecting ends 1221, 1222 of the elastic clamping sections 122 for supporting the two elastic clamping sections 122. It is noted the two connecting sections 123 are not in contact with the flattened section 112. In the drawings, the two elastic clamping sections 122 are represented as being symmetrically arranged and transversely extended relative to the flattened section 112 while the two connecting sections 123 are symmetrically arranged and vertically extended relative to the flattened section 112, such that for corners are formed at joints of the elastic clamping sections 122 and the connecting sections 123. In the illustrated preferred embodiment, the clamp collar 12 is integrally formed by injection molding or 3D printing.
Before the clamp collar 12 is fitted on around the flattened section 112, the two elastic clamping sections 122 and the two connecting sections 123 are outward pulled to expand the elastically deformable space 121, such that the clamp collar 12 can be conveniently moved through the front section 111 or the rear section 113 of the floating heat pipe 11 to the flattened section 112. When the clamp collar 12 has been moved to the flattened section 112, the two elastic clamping sections 122 and the two connecting sections 123 are released and they can elastically restore their original positions. Meanwhile, the elastically deformable space 121 is also restored its original condition.
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The present invention has been described with some preferred embodiments thereof and it is understood that many changes and modifications in the described embodiments can be carried out without departing from the scope and the spirit of the invention that is intended to be limited only by the appended claims.