The present invention relates generally to a heat dissipation unit connection structure, and more particularly to a heat dissipation unit connection structure, which can quickly connect the heat dissipation units and save the connection cost.
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The conventional inserted roll-bond plate evaporators 5 can be classified into two types of structures. One is single-face roll-bond plate evaporator and the other is double-face roll-bond plate evaporator. The single-face roll-bond plate evaporator has a plane face and another face formed with the blown and raised pipelines. The double-face roll-bond plate evaporator has two faces both of which are formed with the blown and raised pipelines. The above two types of roll-bond plate evaporators 5 are both two-piece units assembled by means of adhesion or welding. A chamber is defined between the two units and a working gas is filled in the chamber. The roll-bond plate evaporator 5 has a free end 51 and a fixed end 52. The free end 51 has multiple locating bosses 511.
The fixed end of the roll-bond plate evaporator 5 is fixed in a channel 61 formed on a substrate 6. The substrate 6 is in contact with a heat source to conduct the heat thereof. The free end of the roll-bond plate evaporator 5 is connected with a plate body 7. The plate body 7 is formed with multiple perforations 71 in a position corresponding to the locating bosses 511 of the free ends 51 of the roll-bond plate evaporators 5. The locating bosses 511 are inserted in the perforations 71 and then fixed by means of welding or the like. The plate body 7 serves to provide dustproof effect and secure the roll-bond plate evaporators 5 to prevent the roll-bond plate evaporators 5 from being flexed and deformed. The connection method for assembling the plate body 7 with the conventional roll-bond plate evaporators 5 is relatively complicated. It is necessary to precisely align the roll-bond plate evaporators 5 with the plate body 7 and then weld the roll-bond plate evaporators 5 with the plate body 7. Such process is time-costing and the difficulty in working is increased. Moreover, once assembled, it is impossible or very hard to rework on the plate body 7. Furthermore, the securing structure of the conventional roll-bond plate evaporators 5 is too complicated so that the manufacturing cost is relatively high.
It is therefore tried by the applicant to provide a heat dissipation unit connection structure to improve the shortcomings of the conventional heat dissipation unit connection structure that it is complicated to secure the roll-bond plate evaporators 5 and it is impossible to rework on the roll-bond plate evaporators 5.
It is therefore a primary object of the present invention to provide a heat dissipation unit connection structure, which can easily secure the heat dissipation units and achieve dustproof effect.
To achieve the above and other objects, the heat dissipation unit connection structure of the present invention includes a substrate and multiple heat dissipation units.
The substrate has a first face and a second face. Each heat dissipation unit has a first section and a second section. One end of the first section is connected with the second face of the substrate. The first section has an internal space. The second section extends from the other end of the first section. The second sections of each two adjacent heat dissipation units abut against and connect with each other.
The heat dissipation unit connection structure improves the shortcoming of the conventional heat dissipation unit connection structure that it is necessary to additionally connect a plate body with the free ends of the heat dissipation units so that the connection structure and process are complicated. Therefore, the heat dissipation unit connection structure is simplified and the working time is shortened. Also, the manufacturing cost is lowered.
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:
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The substrate 1 has a first face 11 and a second face 12. The first and second faces 11, 12 are respectively positioned on an upper side and a lower side of the substrate 1. The first face 11 is in contact with at least one heat source (not shown) to conduct the heat of the heat source. The second face 12 is formed with multiple channels 121.
The heat dissipation units 2 are made of a material selected from a group consisting of gold, silver, copper, aluminum, commercial pure titanium, titanium alloy, stainless steel, ceramic material, ceramic aluminum-based complex material and any combination thereof. Each heat dissipation unit 2 has a first section 21 and a second section 22. The first section 21 has an internal space 211, which is an airtight chamber or flow passage. In this embodiment, the space 211 is, but not limited to, an airtight chamber 211 for illustration purposes. A working fluid 3 is filled in the airtight chamber 211. The working fluid 3 can be a gas or a liquid. The first section 21 is a section for two-phase (vapor phase and liquid phase) heat exchange. Various working fluids 3 can be filled in the airtight chamber 211 to achieve vapor-liquid circulation heat exchange effect. Alternatively, the internal space 211 of the first section 21 can be a flow passage. A roughened structure or a capillary structure can be selectively disposed in the flow passage to enhance the backflow effect of the working fluid 3.
One end of the first section 21 is connected with and inserted in the channel 121 of the second face 12 of the substrate 1. The end of the first section 21 that is connected with the channel 121 is an engagement end 212. The channel 121 has an engagement notch 1211 corresponding to the engagement end 212. The engagement end 212 is correspondingly engaged with the engagement notch 1211. The first section 21 of the heat dissipation unit 2 is securely connected with the channel 121 of the substrate 1 by means of press fit, welding, adhesion, insertion or engagement. Alternatively, the engagement end 212 and the engagement notch 1211 can be a dovetailed tenon and a cooperative dovetailed mortise, which are assembled with each other (not shown).
The second section 22 extends from the other end of the first section 21. The second sections 22 of each two adjacent heat dissipation units 2 abut against and connect/assemble with each other. The first and second sections 21, 22 are normal to each other. The second section 22 has at least one vent 223. The second sections 22 not only serve to provide dustproof effect, but also serve to enlarge the total heat dissipation area of the heat dissipation units 2. The second section 22 has a first end 221 and a second end 222. The second end 222 is positioned at a junction between the first and second sections 21, 22. The first end 221 is a free end of the second section 22. The first and second ends 221, 222 of the second sections 22 of each two adjacent heat dissipation units 2 abut against and connect/assemble with each other, whereby the second sections 22 normal to the first sections 21 can enhance the structural strength and provide dustproof effect. In addition, the second sections 22 of each two adjacent heat dissipation units 2 can be further securely connected with each other by means of engagement, latching, welding, adhesion or hooping to increase the connection strength.
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In the following embodiments, the second sections 22 of each two adjacent heat dissipation units 2 are formed with connection structures, which are connected with each other by means of engagement or latching to securely connect the adjacent heat dissipation units 2 with each other.
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The latch section 2211 and the latched section 2221 have some other aspects (as shown in
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According to the above arrangement, the second sections 22 perpendicularly extending from the first sections 21 can enhance the structural strength of the free ends of the heat dissipation units 2 and provide dustproof effect. Moreover, the second sections 22 are additionally formed with the latch sections 2211 and the latched sections 2221, which are latched with each other. Therefore, the second sections 22 of the two adjacent heat dissipation units 2 can be connected without welding or adhesion or any other means. Accordingly, the working time and the manufacturing cost for the welding or adhesion can be saved.
The present invention has been described with the above embodiments thereof and it is understood that many changes and modifications in such as the form or layout pattern or practicing step of the above 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.