The present application relates to heat exchange techniques, and more specifically, to a heat dissipation apparatus and an outdoor communication device.
In communication networks, there are a large number of outdoor communication devices arranged in open fields, for example, large power cabinets of communication base stations. Because these outdoor communication devices produce heat in their operation, and they can only operate appropriately in a certain range of temperatures, heat dissipation apparatus must be disposed for these outdoor communication devices.
When constructing communication networks, operators provide corresponding numbers of service boards in their outdoor communication devices according to their service demands, and always preserve some spare slots for service board arrangement. After the original construction of communication networks, dilation in communication networks is needed with the increase of service demands, thus, additional service boards may be inserted in the above spare slots to realize update of outdoor communication devices. After update, there may be a change in the working power of an outdoor communication device, as a result, a heat dissipation apparatus provided in the original construction of a communication network may be no longer suitable for the updated outdoor communication device. Presently, in the design of a heat dissipation apparatus, if the probability of sequential updates of an outdoor communication device is considered, the heat dissipation apparatus has to be designed according to the working power when a maximum number of service boards are provided for the outdoor communication device, thereby, manufacturing cost may increase, and there may be a waste in cost if the outdoor communication device is not provided with a maximum number of service boards. However, if a heat dissipation apparatus is provided only according to the working power of an outdoor communication device specified in the original communication network construction, if a update is needed for the outdoor communication device later, the outdoor communication device must be replaced as a whole, leading to a larger waste in cost. In summary, the existing heat dissipation apparatus can not be updated synchronization with outdoor communication devices, leading to waste in production cost of outdoor communication devices.
A heat dissipation apparatus is provided in one embodiment for addressing defects in the prior art and lowering manufacturing cost.
An outdoor communication device is provided in one embodiment for addressing defects in the prior art and lowering manufacturing cost.
A heat dissipation device is further provided in one embodiment and comprises: one or more thermosiphon heat exchange units, one or more first partitions, and a frame having at least two lattices; wherein
each of the one or more thermosiphon heat exchange units is embedded in one lattice of the at least two lattices;
each lattice of the at least two lattices having no thermosiphon heat exchange unit embedded is disposed with the first partition to partition the lattice into an upper portion and a lower portion, wherein the first partition is detachable.
An outdoor communication device comprising the above heat dissipation apparatus is further provided in one embodiment and the outdoor communication device comprises: one or more service boards; wherein,
the number of the thermosiphon heat exchange units is determined according to the number of the service boards.
From the above technical solution, it can be seen that, in embodiments, through modular design, the frame of a heat dissipation apparatus may have a plurality of lattices in each of which a thermosiphon heat exchange unit can be embedded, the number of the embedded thermosiphon heat exchange units can be increased or decreased at any time depending on heat dissipation performance that is required, the synchronized update of the heat dissipation apparatus with the device where the heat dissipation apparatus is disposed can be implemented, a waste in cost caused when the heat dissipation apparatus is designed according to its maximum required heat dissipation performance can be avoided, and manufacturing cost can be saved. Furthermore, the heat dissipation apparatus is plug-and-play, which may facilitate mount and maintenance, and the update requirement of devices can be met.
For a more explicit description of technical solutions of embodiments or the prior art, a brief introduction of accompanying drawings to be used in the description of these embodiments and the prior art will be given below. Obviously, accompanying drawings described below are merely some embodiments, for those skilled in the art, other accompanying drawings can be derived from these ones without any creative efforts.
For a better clarity of objects, technical solutions, and advantages of the embodiments, a clear and complete description of technical solutions of embodiments will be given in connection with accompanying drawings of those embodiments. Obviously, embodiments described herein are merely some embodiments, but not all of them. Based on those embodiments, other embodiments can occur to those skilled in the art without any creative efforts, all of which fall within the scope claims.
Based on the above technical solution, the heat dissipation apparatus may further comprise: at least a fan unit 4. Particularly, each fan unit 4 is embedded in a half lattice constructed by the frame 3 and a first partition 2.
Hereinafter, through Embodiment 2, a detail description will be given for the thermosiphon heat exchange unit 1 of the above technical solution.
The cooling fins 14 described above may have various shapes, preferably, the cooling fins 14 described above are ripple-shaped cooling fins.
Refrigerant is accommodated in the vapor end collection pipe 12, condensation end collection pipe 11, and cooling tubules 13. Particularly, the refrigerant may be, but not limit to, any one of the following materials: ammonia, acetone, or R134A type refrigerant.
The thermosiphon heat exchange unit 1 is portioned by the second partition 15. The lower portion of the partitioned thermosiphon heat exchange unit 1 comprises the vapor end collection pipe 12 and the lower portion of each cooling tubule 13, which is arranged in an internal circulation air passage to contact with the heat air produced by a device where the heat dissipation apparatus is provided. In the cooling tubules 13 at the lower portion, liquid refrigerant makes heat exchange with heat air, the refrigerant absorbing heat and then turning into vapor through vaporization. The vapor rises into the upper portion of the thermosiphon heat exchange unit 1 that is portioned along the cooling tubules 13. The portioned upper portion of the thermosiphon heat exchange unit 1 comprises the condensation end collection pipe 11 and the upper portion of each cooling tubule 13, which is arranged in an external circulation air passage to contact with the cool air outside of the heat dissipation apparatus. In the cooling tubules 13 at the upper portion, refrigerant vapor makes heat exchange with the cool air to disperse heat, and then returns into liquid state through condensation. Liquid refrigerant flows downward along the cooling tubules 13 due to gravity, returning to the lower portion of the thermosiphon heat exchange unit 1 that is portioned. Through such an interchanging circulation, heat in the interior of the heat dissipation apparatus can be transmitted to the outside to realize heat dissipation.
In the assembled heat dissipation apparatus, a plurality of lattices each are partitioned into upper and lower portions with a plurality of first partitions 2. Wherein, the lower portion of all of the lattices is arranged in an internal circulation air passage to contact with heat air produced by a device where the heat dissipation apparatus is located. The upper portion of all of the lattices is arranged in an external circulation air passage to contact cool air outside the heat dissipation apparatus. The internal circulation air passage is isolated from the external circulation air passage by a plurality of first partitions 2.
In practical applications, the number of the thermosiphon heat exchange units 1 is determined according to required heat dissipation performance. W hen the outdoor communication device where the heat dissipation apparatus is located is updated, first partitions 2 in lattices having no thermosiphon heat exchange units 1 embedded currently can be removed to embed new thermosiphon heat exchange units 1, so that heat dissipation performance of the heat dissipation apparatus can be improved. In Embodiment 3, only 2 thermosiphon heat exchange units 1 are provided as an example.
Furthermore, the number of fan units 4 also can be determined according to required heat dissipation performance. When it is required to improve heat dissipation performance, newly added fan units 4 can be embedded in half lattices constructed by the frame 3 and first partitions 2. Also, according to the strength of air flow in the internal circulation air passage and the external circulation air passage, the same number or different numbers of fan units 4 can be disposed in the internal circulation air passage and the external circulation air passage. When adding new fan units 4, it is possible to add new fan units 4 in merely one of the internal circulation air passage and the external circulation air passage if necessary. In Embodiment 3, only one fan unit 4 is disposed in each of the internal circulation air passage and the external circulation air passage as an exemple.
In Embodiment 3, preferably, the lattice, the thermosiphon heat exchange unit 1 and the fan unit 4 are all rectangular. Particularly, the lattice and the thermosiphon heat exchange unit may have the same shape. The width of the fan unit 4 is equal to the width of the lattice and the thermosiphon heat exchange unit 1, the height of the fan unit 4 is half of the height of the lattice and the thermosiphon heat exchange unit 1. In other embodiments, the lattice, the thermosiphon heat exchange unit 1, and the fan unit 4 may have other shapes.
The heat dissipation apparatus of any one of Embodiment 1 to Embodiment 3 can be applied to an outdoor communication device. Particularly, the outdoor communication device comprises the heat dissipation apparatus and one or more service boards, the heat dissipation apparatus being one mentioned in any one of Embodiment 1 to Embodiment 3. The number of the thermosiphon heat exchange units in the heat dissipation apparatus can be determined according to the number of the service boards. When the outdoor communication device is updated, the number of the service boards may increase, and additional heat dissipation apparatus may be added in the heat dissipation apparatus correspondingly. Further, the number of the fan units in the heat dissipation apparatus also can be determined based on the number of the service boards. When the outdoor communication device is updated, the number of the service boards may increase, fan units may be added in the heat dissipation apparatus correspondingly.
In Embodiment 1 to Embodiment 3, a modular design is adopted, the frame of the heat dissipation apparatus has a plurality of lattices in which a plurality of thermosiphon heat exchange units can be embedded, the number of the embedded thermosiphon heat exchange units can be increased or decreased at any time depending on heat dissipation performance that is required currently, the synchronized update of the heat dissipation apparatus with the device where the heat dissipation apparatus is disposed can be implemented, a waste in cost caused when the heat dissipation apparatus is designed according to its maximum required heat dissipation performance can be avoided, and manufacturing cost can be saved. In addition, the heat dissipation apparatus is plug-and-play, which may facilitate mount and maintenance, and the update requirement of devices can be met.
Note that every method embodiment described above is described with a combination of a series of actions, however, it will be appreciated by those skilled in the art that this invention do not limit to the action sequence described herein, as according to this invention some steps can be carried out in other orders or simultaneously. Secondly, those skilled in the art should understand that the embodiments described in this specification are all preferable embodiments, and actions or modules involved in these embodiments are not necessarily needed by this invention.
In the above embodiments, each of them is emphasized differently, so parts that are not detailed in one embodiment can be found in the relative description of other embodiments.
Those ordinary skilled in the art may understand that all or part steps of the above method embodiments can be implemented by program instructions relevant hardware, the program described above can be stored in a computer readable storage medium, which when executed may perform steps contained in the above method embodiments. The storage medium described above may comprise: ROM, RAM, magnetic disks, optical disks and various mediums capable of storing program codes.
At last, it should be noted that the above embodiments are merely given to illustrate a technical solution that falls within the scope of the claims and are not intended as limitations. Those skilled in the art may appreciate that modifications to the technical solution described in various embodiment or alternations of its some parts can be made. Such modifications and alternations are understood to fall within the scope of the claims.
This application is a continuation of International Application No. PCT/CN2011/074103, filed on May 16, 2011, which is hereby incorporated by reference in its entirety.
Number | Date | Country | |
---|---|---|---|
Parent | PCT/CN2011/074103 | May 2011 | US |
Child | 13472974 | US |