CN215956922U - Combined 5G base station radiator - Google Patents
Combined 5G base station radiator Download PDFInfo
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- CN215956922U CN215956922U CN202121386274.0U CN202121386274U CN215956922U CN 215956922 U CN215956922 U CN 215956922U CN 202121386274 U CN202121386274 U CN 202121386274U CN 215956922 U CN215956922 U CN 215956922U
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Abstract
The utility model relates to the technical field of base station radiators, and discloses a combined 5G base station radiator which comprises a 5G base station body, wherein the bottom of the 5G base station body is connected with a base station plug block, a base station stabilizing base is arranged on the lower side of the base station plug block, a base slot matched with the base station plug block is formed in the base station stabilizing base, a concave radiator is connected onto the G base station body, and a plurality of radiating fins which are arranged at equal intervals are connected onto the concave radiator. This combination formula 5G basic station radiator stabilizes base, basic station inserted block, 5G basic station body and base slot's cooperation through the basic station, makes the difficult slope of 5G basic station body, makes 5G basic station body more firm, through the cooperation of concave type radiator, basic station spout, radiator T type slider, fin T type slider, fin recess, cylinder, hot connecting plate, fin draw-in groove and radiator T type spout for the efficiency of equipment.
Description
Technical Field
The utility model relates to the technical field of base station radiators, in particular to a combined 5G base station radiator.
Background
A base station, i.e. a public mobile communication base station, is an interface device for a mobile device to access the internet, and is a form of a radio station, which is a radio transceiver station for information transmission with a mobile phone terminal through a mobile communication switching center in a certain radio coverage area. The construction of mobile communication base stations is an important part of the investment of mobile communication operators, and is generally carried out around the factors of coverage, call quality, investment benefit, difficult construction, convenient maintenance and the like. With the development of mobile communication network services towards datamation and packetization, the development trend of mobile communication base stations is also necessarily broadband, large-coverage construction and IP, and heat generated by machinery or other appliances in the working process is transferred in time to avoid influencing the normal operation of the equipment or instruments. Common radiators can be divided into various types such as air cooling, heat pipe radiators, liquid cooling, semiconductor refrigeration, compressor refrigeration and the like according to the heat dissipation mode, and the high temperature is a large enemy of integrated circuits as is well known. The high temperature can not only cause the unstable operation of the system and shorten the service life, but also possibly burn some parts. The heat that causes the high temperature does not come from outside the computer, but inside the computer, or inside the integrated circuit. The radiator is used for absorbing the heat and then radiating the heat into the case or out of the case, so that the temperature of the computer components is ensured to be normal. Most heat sinks absorb heat by contacting the surfaces of heat-generating components, and then transfer the heat to a remote location by various methods, such as air in a chassis, and then the chassis transfers the hot air to the outside of the chassis, thereby dissipating heat from the computer. The types of radiators are very many, and CPUs, display cards, mainboard chip sets, hard disks, cases, power supplies and even optical drives and memories all need radiators, and the different radiators cannot be used in a mixed manner, wherein the radiator of the CPU is the most frequently contacted. According to the way of taking away heat from the heat sink, the heat sink of the computer can be divided into active heat dissipation and passive heat dissipation. The former is commonly an air-cooled heat sink, while the latter is commonly a heat sink. The further subdivision heat dissipation mode can be divided into air cooling, heat pipes, liquid cooling, semiconductor refrigeration and compressor refrigeration, and the heat dissipation mode refers to the main mode of heat dissipation of the radiator. In thermodynamics, heat dissipation is heat transfer, and the heat transfer mode mainly includes three types: thermal conduction, thermal convection and thermal radiation. The transfer of energy, either by itself or when in contact with a substance, is known as thermal conduction, which is one of the most common ways of heat transfer. For example, the way that the heat sink base of the CPU directly contacts with the CPU to remove heat belongs to heat conduction. The 5G base station is a core device of the 5G network, provides wireless coverage, and realizes wireless signal transmission between a wired communication network and a wireless terminal. The architecture and morphology of the base station directly affect how the 5G network is deployed. In the technical standard, the frequency band of 5G is much higher than that of 2G, 3G and 4G networks, and the 5G network mainly works in the frequency band of 3000-5000MHz at present. The base station density of a 5G network will be higher since the higher the frequency, the greater the attenuation in the signal propagation. The 5G base station AAU adopts a MassiveMIMO (massive multiple input multiple output) technology to increase the power of equipment, and the power of the 5G base station is about 3-4 times that of the 4G base station; meanwhile, the 5G base stations and the existing base stations are constructed in a large number of co-stations, so that great difficulty is brought to the matched power of the base stations, however, the existing 5G base stations are high in power and poor in heat dissipation, and the existing aluminum profile cooling fins cannot be flexibly adjusted according to the 5G base stations with different structures and shapes; therefore, the existing requirements are not met, and a combined 5G base station radiator is provided for the requirement.
Some base station radiators on the market today:
(1) in the using process, due to the reason that the radiator needs to be assembled, the existing base station radiator is complex in assembling procedure;
(2) in use, the conventional base station is unstable when standing upright due to the tendency of the base station to tilt when standing upright.
We therefore propose a modular 5G base station heat sink to address the problems set out above.
SUMMERY OF THE UTILITY MODEL
Technical problem to be solved
In view of the above-mentioned shortcomings in the prior art, an object of the present invention is to provide a combined 5G base station heat sink, so as to solve the problems of complicated assembly procedure of the base station heat sink and instability of the base station when the base station is erected, which are presented in the above-mentioned background art, in some combined 5G base station heat sinks in the current market.
(II) technical scheme
In order to achieve the purpose, the utility model is realized by the following technical scheme:
a combined 5G base station radiator comprises a 5G base station body, wherein a base station plug block is connected to the bottom of the 5G base station body, a base station stabilizing base is arranged on the lower side of the base station plug block, a base slot matched with the base station plug block is formed in the base station stabilizing base, and a concave radiator is connected to the 5G base station body;
the concave radiator is connected with a plurality of radiating fins which are arranged equidistantly, radiating fin grooves are formed in the radiating fins, cylinders are arranged inside the radiating fin grooves, a plurality of radiating connecting plates are arranged on the cylinders, connecting plate through holes matched with the cylinders are formed in the radiating connecting plates, and radiating fin clamping grooves matched with the radiating connecting plates are formed in the radiating fins.
Preferably, the base condensation groove has been seted up to the inside of basic station stabilizing base, the inside of base condensation groove is provided with the condensate, the condensation port has been seted up on the basic station stabilizing base, condensation port and base condensation groove communicate with each other, one side of concave type radiator and one side swing joint of 5G base station body, it is a plurality of the fin is equidistant between two liang, and is a plurality of one side of fin all with the inner wall swing joint of concave type radiator.
Preferably, one side of the concave radiator is movably connected with one side of the 5G base station body through a first sliding mechanism, one side of the radiating fins is movably connected with the inner wall of the concave radiator through a second sliding mechanism, and the top of the 5G base station body is fixedly provided with the radiating plate.
Preferably, two radiator T-shaped sliding blocks which are arranged equidistantly are fixed on one side of the concave radiator, the two radiator T-shaped sliding blocks are centrosymmetric by taking the concave radiator as a center, four base station sliding grooves which are arranged equidistantly and are matched with the radiator T-shaped sliding blocks are arranged on the 5G base station body, the concave radiator is in sliding connection with the base station sliding grooves of the 5G base station body through the radiator T-shaped sliding blocks, a radiating fin T-shaped sliding block is fixed on one side of each radiating fin, a plurality of radiator T-shaped sliding grooves which are arranged equidistantly and are matched with the radiating fin T-shaped sliding blocks are arranged on the concave radiator, the radiating fins are in sliding connection with the radiator T-shaped sliding grooves of the concave radiator through the radiating fin T-shaped sliding blocks, the maximum width value of the radiator T-shaped sliding blocks is not more than the minimum width value of the base station sliding grooves, and the maximum length value of the radiator T-shaped sliding blocks is not more than the minimum length value of the base station sliding grooves, the maximum width value of the radiating fin T-shaped sliding block does not exceed the minimum width value of the radiator T-shaped sliding groove, and the maximum length value of the radiating fin T-shaped sliding block does not exceed the minimum length value of the radiator T-shaped sliding groove.
Furthermore, a base station plug block of the 5G base station body is connected with a base slot of the base station stabilizing base in an inserting mode, the maximum length value of the base station plug block does not exceed the minimum length value of the base slot, the maximum width value of the base station plug block does not exceed the minimum width value of the base slot, and the top of the base station plug block is fixed with the bottom of the 5G base station body.
Further, the heat-sinking connection board passes through connecting plate through-hole and cylinder swing joint, the columniform maximum diameter value is no longer than the minimum diameter value of connecting plate through-hole, the fin draw-in groove looks joint of heat-sinking connection board and fin, the maximum width value of heat-sinking connection board is no longer than the minimum width value of fin draw-in groove, the maximum length value of heat-sinking connection board is no longer than the minimum length value of fin draw-in groove.
Furthermore, a plurality of radiating holes are formed in the radiating fins and are arranged at equal intervals, and the distance between every two radiating holes is equal.
(III) advantageous effects
Compared with the prior art, the utility model has the beneficial effects that: this combination formula 5G base station radiator:
(1) through the cooperation of basic station stabilizing base, basic station inserted block, 5G basic station body and base slot, make the difficult slope of 5G basic station body, make 5G basic station body more firm.
(2) Through the cooperation of concave radiator, basic station spout, radiator T type slider, fin T type slider, fin recess, cylinder, heat-radiating connecting plate, fin draw-in groove and radiator T type spout for the efficiency of equipment.
Drawings
Fig. 1 is a schematic perspective view of a combined 5G base station radiator in a first view according to the present invention;
FIG. 2 is a schematic partial perspective view of a combined 5G base station heat sink according to the present invention from a second perspective;
FIG. 3 is a schematic view of a heat-dissipating connecting plate of the combined type 5G base station heat sink according to the present invention;
FIG. 4 is a schematic cross-sectional view of a base station stabilizer base of the combined 5G base station heat sink of the present invention;
fig. 5 is a schematic perspective view of a combined 5G base station radiator according to a third aspect of the present invention;
fig. 6 is a schematic perspective view of a combined type 5G base station radiator in a fourth view angle.
In the figure: 5G basic station body 1, basic station stable base 2, basic station inserted block 3, base slot 4, base condensate tank 5, condensate 6, condensation port 7, concave type radiator 8, fin 9, fin T type slider 10, louvre 11, fin recess 12, cylinder 13, heat-radiating connecting plate 14, fin draw-in groove 15, connecting plate through-hole 16, fin T type slider 17, basic station spout 18, heating panel 19, fin T type spout 20.
Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.
Referring to fig. 1-6, the present invention provides a combined 5G base station heat sink; the base station comprises a 5G base station body 1 and is characterized in that a base station insert block 3 is connected to the bottom of the 5G base station body 1, a base station stabilizing base 2 is arranged on the lower side of the base station insert block 3, a base slot 4 matched with the base station insert block 3 is formed in the base station stabilizing base 2, and a concave radiator 8 is connected to the 5G base station body 1;
the concave radiator 8 is connected with a plurality of radiating fins 9 which are arranged at equal intervals, radiating fin grooves 12 are formed in the plurality of radiating fins 9, cylinders 13 are arranged inside the plurality of radiating fin grooves 12, radiating connecting plates 14 are arranged on the plurality of cylinders 13, connecting plate through holes 16 matched with the cylinders 13 are formed in the plurality of radiating connecting plates 14, and radiating fin clamping grooves 15 matched with the radiating connecting plates 14 are formed in the plurality of radiating fins 9;
as a preferred technical scheme of the utility model: a base condensation groove 5 is formed in the base station stabilizing base 2, condensate 6 is arranged in the base condensation groove 5, a condensation port 7 is formed in the base station stabilizing base 2, the condensation port 7 is communicated with the base condensation groove 5, one side of a concave radiator 8 is movably connected with one side of a 5G base station body 1, the distances between every two cooling fins 9 are equal, one sides of the cooling fins 9 are movably connected with the inner wall of the concave radiator 8, and the bottom of the 5G base station body 1 is cooled through the matching of the condensate 6 and the base condensation groove 5;
as a preferred technical scheme of the utility model: one side of the concave radiator 8 is movably connected with one side of the 5G base station body 1 through a first sliding mechanism, one sides of the radiating fins 9 are movably connected with the inner wall of the concave radiator 8 through a second sliding mechanism, a radiating plate 19 is fixed at the top of the 5G base station body 1, and the top of the 5G base station body 1 is protected through the radiating plate 19;
as a preferred technical scheme of the utility model: two radiator T-shaped sliding blocks 17 which are arranged equidistantly are fixed on one side of a concave radiator 8, the two radiator T-shaped sliding blocks 17 are centrosymmetric by taking the concave radiator 8 as a center, four base station sliding grooves 18 which are arranged equidistantly and are matched with the radiator T-shaped sliding blocks 17 are arranged on a 5G base station body 1, the concave radiator 8 is in sliding connection with the base station sliding grooves 18 of the 5G base station body 1 through the radiator T-shaped sliding blocks 17, a radiating fin T-shaped sliding block 10 is fixed on one side of a plurality of radiating fins 9, a plurality of radiator T-shaped sliding grooves 20 which are arranged equidistantly and are matched with the radiating fin T-shaped sliding blocks 10 are arranged on the concave radiator 8, the radiating fins 9 are in sliding connection with the radiator T-shaped sliding grooves 20 of the concave radiator 8 through the radiating fin T-shaped sliding blocks 10, the maximum width value of the radiator T-shaped sliding blocks 17 does not exceed the minimum width value of the base station sliding grooves 18, the maximum length value of the radiator T-shaped sliding blocks 17 does not exceed the minimum length value of the base station sliding grooves 18, the maximum width value of the radiating fin T-shaped sliding block 10 is not more than the minimum width value of the radiator T-shaped sliding groove 20, the maximum length value of the radiating fin T-shaped sliding block 10 is not more than the minimum length value of the radiator T-shaped sliding groove 20, and the heat dissipation efficiency of the 5G base station body 1 is improved through the radiating fins 9 and the concave radiator 8;
as a preferred technical scheme of the utility model: a base station plug 3 of a 5G base station body 1 is inserted into a base slot 4 of a base station stabilizing base 2, the maximum length value of the base station plug 3 is not more than the minimum length value of the base slot 4, the maximum width value of the base station plug 3 is not more than the minimum width value of the base slot 4, the top of the base station plug 3 is fixed with the bottom of the 5G base station body 1, and the stability of the 5G base station body 1 is enhanced through the matching of the base station plug 3 and the base station stabilizing base 2;
as a preferred technical scheme of the utility model: the heat dissipation connecting plate 14 is movably connected with the cylinder 13 through a connecting plate through hole 16, the maximum diameter value of the cylinder 13 is not more than the minimum diameter value of the connecting plate through hole 16, the heat dissipation connecting plate 14 is clamped with a heat dissipation fin clamping groove 15 of the heat dissipation fin 9, the maximum width value of the heat dissipation connecting plate 14 is not more than the minimum width value of the heat dissipation fin clamping groove 15, the maximum length value of the heat dissipation connecting plate 14 is not more than the minimum length value of the heat dissipation fin clamping groove 15, and the heat dissipation connecting plate 14 is matched with the heat dissipation fin clamping groove 15 to enable the heat dissipation fins 9 to be stably supported with one another;
as a preferred technical scheme of the utility model: the heat sink 9 is provided with a plurality of heat dissipation holes 11 arranged at equal intervals, and the distances between every two heat dissipation holes 11 are equal.
The working principle of the embodiment is as follows: when the combined type 5G base station radiator is used, as shown in fig. 1-6, a radiator T-shaped slider 17 of a concave radiator 8 is inserted into a base station chute 18 of a 5G base station body 1, a radiator T-shaped slider 10 of a radiator 9 is inserted into a radiator T-shaped chute 20 of the concave radiator 8, a radiator groove 12 of the radiator 9 is upward, a radiator connecting plate 14 is pulled out of an upward state and inserted into a radiator clamping groove 15, and condensate 6 is poured into a base condensation groove 5 through a condensation port 7, which is the working process of the whole device, and the content which is not described in detail in the description belongs to the prior art known by persons skilled in the art.
Although the present invention has been described in detail with reference to the foregoing embodiments, it should be noted that, in the present invention, unless otherwise explicitly specified or limited, the terms "disposed," "mounted," "connected," "fixed," and the like are to be construed broadly, and for example, may be fixedly connected or detachably connected; or indirectly through an intermediary. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations; it will be apparent to those skilled in the art that modifications and equivalents may be made in the embodiments and/or portions thereof without departing from the spirit and scope of the present invention.
Claims (7)
1. A combined 5G base station radiator comprises a 5G base station body (1), and is characterized in that the bottom of the 5G base station body (1) is connected with a base station plug block (3), a base station stabilizing base (2) is arranged on the lower side of the base station plug block (3), a base slot (4) matched with the base station plug block (3) is formed in the base station stabilizing base (2), and a concave radiator (8) is connected to the 5G base station body (1);
be connected with fin (9) that a plurality of equidistance were arranged on concave type radiator (8), it is a plurality of fin recess (12) have all been seted up on fin (9), it is a plurality of the inside of fin recess (12) all is provided with cylinder (13), and is a plurality of all be provided with on cylinder (13) heat-radiating connecting plate (14), it is a plurality of all set up on heat-radiating connecting plate (14) connecting plate through-hole (16) with cylinder (13) looks adaptation, it is a plurality of all set up fin draw-in groove (15) with heat-radiating connecting plate (14) looks adaptation on fin (9).
2. The combined type 5G base station radiator according to claim 1, wherein a base condensation groove (5) is formed in the base station stabilizing base (2), condensate (6) is arranged in the base condensation groove (5), a condensation port (7) is formed in the base station stabilizing base (2), the condensation port (7) is communicated with the base condensation groove (5), one side of the concave radiator (8) is movably connected with one side of the 5G base station body (1), the distance between every two of the plurality of radiating fins (9) is equal, and one side of each of the plurality of radiating fins (9) is movably connected with the inner wall of the concave radiator (8).
3. The combined type 5G base station radiator according to claim 1, wherein one side of the concave radiator (8) is movably connected with one side of the 5G base station body (1) through a first sliding mechanism, one sides of the plurality of radiating fins (9) are movably connected with the inner wall of the concave radiator (8) through a second sliding mechanism, and a radiating plate (19) is fixed at the top of the 5G base station body (1).
4. The combined type 5G base station radiator according to claim 1, wherein one side of the concave radiator (8) is fixed with two radiator T-shaped sliding blocks (17) which are arranged equidistantly, the two radiator T-shaped sliding blocks (17) are symmetrical by taking the concave radiator (8) as a center, the 5G base station body (1) is provided with four base station sliding grooves (18) which are arranged equidistantly and are matched with the radiator T-shaped sliding blocks (17), the concave radiator (8) is connected with the base station sliding grooves (18) of the 5G base station body (1) in a sliding manner through the radiator T-shaped sliding blocks (17), one side of each of the plurality of radiating fins (9) is fixed with a radiating fin T-shaped sliding block (10), the concave radiator (8) is provided with a plurality of radiator T-shaped sliding grooves (20) which are arranged equidistantly and are matched with the radiating fin T-shaped sliding blocks (10), the radiating fin (9) is in sliding connection with a T-shaped sliding groove (20) of a concave radiator (8) through a T-shaped sliding block (10), the maximum width value of the T-shaped sliding block (17) of the radiator is not more than the minimum width value of a base station sliding groove (18), the maximum length value of the T-shaped sliding block (17) of the radiator is not more than the minimum length value of the base station sliding groove (18), the maximum width value of the T-shaped sliding block (10) of the radiating fin is not more than the minimum width value of the T-shaped sliding groove (20) of the radiator, and the maximum length value of the T-shaped sliding block (10) of the radiating fin is not more than the minimum length value of the T-shaped sliding groove (20) of the radiator.
5. The combined 5G base station radiator according to claim 1, wherein the base station plug block (3) of the 5G base station body (1) is inserted into the base slot (4) of the base station stabilizing base (2), the maximum length of the base station plug block (3) does not exceed the minimum length of the base slot (4), the maximum width of the base station plug block (3) does not exceed the minimum width of the base slot (4), and the top of the base station plug block (3) is fixed to the bottom of the 5G base station body (1).
6. The combined type 5G base station radiator according to claim 1, wherein the heat dissipation connecting plate (14) is movably connected with the cylinder (13) through a connecting plate through hole (16), the maximum diameter value of the cylinder (13) does not exceed the minimum diameter value of the connecting plate through hole (16), the heat dissipation connecting plate (14) is clamped with a radiating fin clamping groove (15) of a radiating fin (9), the maximum width value of the heat dissipation connecting plate (14) does not exceed the minimum width value of the radiating fin clamping groove (15), and the maximum length value of the heat dissipation connecting plate (14) does not exceed the minimum length value of the radiating fin clamping groove (15).
7. The combined type 5G base station radiator according to claim 1, wherein the radiating fin (9) is provided with a plurality of radiating holes (11) arranged at equal intervals, and the distances between every two of the plurality of radiating holes (11) are equal.
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Publication number | Priority date | Publication date | Assignee | Title |
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CN114828515A (en) * | 2022-03-08 | 2022-07-29 | 上海艾涛信息科技发展有限公司 | Data center computer room cooling system |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
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CN114828515A (en) * | 2022-03-08 | 2022-07-29 | 上海艾涛信息科技发展有限公司 | Data center computer room cooling system |
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Effective date of registration: 20220926 Address after: Room 101, No. 3, Yiheng Road, Zhongxin Road, Nanyong Street, Qiaonan Street, Panyu District, Guangzhou City, Guangdong Province, 510000 Patentee after: Guangzhou Longfa Aluminum Co.,Ltd. Address before: 311200 Building 1, Huarui center, Xiaoshan Economic and Technological Development Zone, Xiaoshan District, Hangzhou City, Zhejiang Province Patentee before: Chai Zhihui |
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