CN112911412A - Base station device for 5G communication - Google Patents

Abstract

The invention relates to the technical field of 5G communication, and particularly discloses a base station device for 5G communication, which comprises a cabinet body, wherein a cabinet cavity is arranged in the cabinet body, a through hole on the cabinet is formed in the upper end part of the cabinet body, a heat dissipation cylinder in clearance fit with the through hole on the cabinet is arranged in the cabinet cavity, a plurality of uniformly distributed heat dissipation cylinder through holes are formed in the heat dissipation cylinder, a water collection cylinder with an opening at the upper end is arranged in the heat dissipation cylinder, the upper end part of the water collection cylinder extends out of the through hole on the cabinet, a heat dissipation circular plate is arranged at the end part of the water collection cylinder, which extends out of the through hole on the cabinet, and. When the base station device for 5G communication is used, the antenna device mounting seat can be protected and the cabinet body can be radiated better, so that the base station device for 5G communication has better stability when in use.

Description

Base station device for 5G communication

Technical Field

The present invention relates to the field of 5G communication technologies, and in particular, to a base station apparatus for 5G communication.

Background

The fifth generation mobile communication technology, which is the latest generation cellular mobile communication technology, has performance goals of high data rate, reduced latency, energy saving, cost reduction, increased system capacity, and large-scale device connection, of 5G. 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 base station and the terminal transmit and receive signals through the medium of the antenna.

The current 5G communication base station lacks a better heat dissipation structure, so that the 5G communication base station needs to be dissipated heat through a heat dissipation device such as an air conditioner when in use, which causes larger power consumption.

Disclosure of Invention

In order to solve the technical problem, the invention is solved by the following technical scheme:

the utility model provides a 5G is base station device for communication, it includes the rack body, be equipped with the rack chamber in the rack body, the upper end of rack body is established and is had the through-hole on the rack, be equipped with in the rack chamber with the rack on through-hole clearance fit's a heat dissipation section of thick bamboo, be equipped with a plurality of evenly distributed's a heat dissipation section of thick bamboo through-hole on the heat dissipation section of thick bamboo, be equipped with upper end open-ended water collection cylinder in the heat dissipation section of thick bamboo, the upper end of water collection cylinder stretches out through-hole on the rack, the tip that stretches out through-hole on the rack.

When the base station device for 5G communication is used, the antenna device mounting seat can be protected and the cabinet body can be radiated better, so that the base station device for 5G communication has better stability when in use.

Preferably, the edge of the upper end face of the heat dissipation circular plate is provided with a heat dissipation enclosing plate perpendicular to the heat dissipation circular plate, and the heat dissipation circular plate and the heat dissipation enclosing plate together form a water collecting tank.

Through the arrangement of the heat dissipation enclosing plate, rainwater can better flow into the water collecting cylinder, and the heat dissipation effect is better improved.

Preferably, the water collecting tank is internally provided with strip-shaped heat dissipation plates distributed along the circumferential direction of the heat dissipation cylinder.

Through the arrangement of the strip-shaped heat dissipation plate, the heat dissipation effect can be better improved.

Preferably, the inner wall of the water collecting cylinder is provided with a plurality of uniform capillary tubes, and the upper end parts of the capillary tubes extend into the water collecting tank.

Through the arrangement of the capillary tube, water flow in the water collecting cylinder moves to the heat dissipation circular plate due to the capillary phenomenon, so that the heat dissipation effect on the cabinet body is better improved.

Preferably, a rotating plate positioned below the radiating circular plate is arranged at the end part of the radiating cylinder extending out of the cabinet cavity, and a plurality of choke plates distributed along the circumferential direction of the radiating cylinder are arranged between the rotating plate and the radiating circular plate; the upper end face of the machine cabinet body is located at the end part of the through hole in the machine cabinet and protrudes upwards to form a boss on the machine cabinet, and the edge of the lower end face of the rotating plate is provided with a lower enclosing plate of the rotating plate.

Through the arrangement of the wind-blocking plate, water flow on the heat-radiating circular plate can be uniformly distributed on the heat-radiating circular plate when wind exists, and meanwhile, the heat-radiating effect of the cabinet body is better improved.

Preferably, a spring mounting cylinder which is positioned right below the heat dissipation cylinder is arranged at the bottom end of the cabinet cavity, the inner wall of the upper end part of the spring mounting cylinder is inwards contracted to form a mounting cylinder flange, the lower end part of the heat dissipation cylinder extends into the spring mounting cylinder, the end part of the heat dissipation cylinder extending into the spring mounting cylinder is provided with a heat dissipation cylinder flange which is in clearance fit with the inner wall of the spring mounting cylinder, and a support spring which is positioned below the heat dissipation cylinder flange and is used for supporting the heat dissipation cylinder is arranged in the spring mounting cylinder; the side walls at two ends of the cabinet body are respectively provided with a plurality of cabinet radiating holes arranged along the height direction of the cabinet body, two guide rails respectively positioned at two ends of the cabinet radiating holes are arranged on the inner wall of the cabinet cavity, guide rail sliders arranged along the length direction of the guide rails are arranged on the two guide rails, and a plurality of sealing strips used for sealing the cabinet radiating holes are arranged between the two guide rail sliders; the connecting rod for connecting the two guide rail sliding blocks is arranged between the guide rail sliding blocks at the two ends in the machine cabinet cavity, the limiting frame is arranged between the two connecting rods and comprises a limiting rod connected with the connecting rod, a limiting ring which is sleeved in the middle of the heat radiating cylinder and is in clearance fit with the heat radiating cylinder is arranged between the two limiting rods, and two limiting flanges which are respectively positioned at the upper end and the lower end of the limiting ring and are matched with the limiting ring are arranged on the outer side wall of the heat radiating cylinder.

Through the matching among the guide rail, the guide rail sliding block, the heat dissipation hole of the machine cabinet and the sealing strip, the heat dissipation of the machine cabinet cavity is better realized, and rainwater in the external environment is prevented from entering the machine cabinet cavity.

Preferably, a lower cabinet through hole is formed in the bottom end of the cabinet body, a fan mounting seat located at the lower cabinet through hole is arranged at the bottom end of the cabinet body, a cabinet fan is arranged in the fan mounting seat, and an air inlet hole is formed in the fan mounting seat; and a displacement sensor for detecting the moving distance of the heat dissipation cylinder is arranged on the outer side wall of the heat dissipation cylinder.

Through the arrangement of the cabinet fan and the displacement sensor, the heat dissipation of the cabinet cavity is better realized, and the resources are better saved.

Preferably, the lower end part of the heat dissipation cylinder is opened, the lower end part of the water collection cylinder penetrates through the lower through hole of the cabinet and extends into the fan mounting seat, a limiting plate for limiting the water collection cylinder is arranged in the lower through hole of the cabinet, a limiting plate through hole in clearance fit with the water collection cylinder is arranged on the limiting plate, and a plurality of air inlet through holes are formed in the limiting plate and are circumferentially arranged along the limiting plate through hole; a third bevel gear is arranged at the end part of the rotating shaft of the cabinet fan, a fourth bevel gear matched with the third bevel gear is arranged at the bottom end part of the water collecting cylinder, and a thermal expansion gasket positioned at the lower end of the supporting spring is arranged in the spring mounting cylinder; the upper end of the cabinet body is provided with a water delivery pipe for delivering water to the water collecting tank, and the end of the water delivery pipe is connected with a water pump.

Through the arrangement of the water pump and the thermal expansion gasket, the heat dissipation effect of the cabinet body is further improved, and the damage of electric elements in the cabinet body caused by overhigh temperature in the cabinet body is avoided, so that the stability of the cabinet body in operation is better improved.

Preferably, a first annular enclosing plate located at the lower through hole of the cabinet is arranged in the spring installation cylinder, a second annular enclosing plate is arranged on the outer side of the first annular enclosing plate, a sleeve installation cavity is formed between the first enclosing plate and the second enclosing plate, a slidable support cylinder is arranged in the sleeve installation cavity, the upper end of the support cylinder extends out of the sleeve installation cavity, a support cylinder flange is arranged at the end part of the support cylinder, which extends out of the sleeve installation cavity, and the upper end of the support spring abuts against the support cylinder flange.

Through the arrangement of the supporting cylinder and the supporting cylinder flange, the direct contact between the supporting spring and the radiating cylinder flange can be avoided, so that the friction force applied to the radiating cylinder during rotation is better reduced.

Preferably, a spring installation cavity is formed between the second enclosing plate and the spring installation barrel, and the supporting spring is arranged in the spring installation cavity.

Through the arrangement of the spring installation cavity, the installation of the supporting spring can be completed conveniently.

Drawings

Fig. 1 is a schematic structural view of an antenna mount in embodiment 1.

Fig. 2 is a cross-sectional view of the antenna mount of fig. 1.

Fig. 3 is a cross-sectional view of the antenna mount of fig. 1.

Fig. 4 is an enlarged view of a portion a in fig. 2.

Fig. 5 is a partial cross-sectional view of the gear mounting shaft of fig. 4.

Fig. 6 is an enlarged view of a portion B in fig. 3.

Fig. 7 is a schematic view of the structure of the upper connecting sleeve in fig. 2.

Fig. 8 is a schematic structural diagram of the cabinet body in embodiment 1.

Fig. 9 is a cross-sectional view of the cabinet body of fig. 8.

Fig. 10 is an enlarged view of a portion C in fig. 9.

Fig. 11 is a schematic structural view of the guide rail, the guide rail slider, the connecting rod, and the limiting frame in embodiment 1.

Fig. 12 is a schematic structural diagram of the limiting plate in fig. 10.

Fig. 13 is a schematic diagram of a control system in embodiment 1.

Detailed Description

For a further understanding of the invention, reference should be made to the following detailed description taken in conjunction with the accompanying drawings and examples. It is to be understood that the examples are illustrative of the invention and not limiting.

Example 1

As shown in fig. 1 to 13, the present embodiment provides a 5G communication system, which includes an antenna mounting base 110, an antenna mounting cavity 210 is disposed in the antenna mounting base 110, and a sealing plate 120 for sealing the antenna mounting cavity 210 is disposed on the antenna mounting base 110; the upper end and the lower end of the antenna mounting seat 110 are both provided with mounting seat through holes 220 communicated with the antenna mounting cavity 210, a supporting mechanism is arranged in the antenna mounting cavity 210, and the upper end and the lower end of the supporting mechanism respectively extend out of the mounting seat through holes 220; still include rack body 810, be equipped with rack chamber 910 in the rack body 810, the upper end of rack body 810 is established and is had on the rack through-hole 920, be equipped with in the rack chamber 910 with the rack on through-hole 920 clearance fit's a heat dissipation section of thick bamboo 930, be equipped with a plurality of evenly distributed's a heat dissipation section of thick bamboo through-hole 940 on the heat dissipation section of thick bamboo 930, be equipped with upper end open-ended water collection cylinder 950 in the heat dissipation section of thick bamboo 930, the upper end of water collection cylinder 950 stretches out on the rack through-hole 920, the tip that stretches out on the water collection cylinder 950 on the rack through-hole 920 is equipped with heat dissipation ple.

In the communication system of embodiment 5G, when the upper end portion and the lower end portion of the antenna mounting base 110 are impacted, the impact is buffered by the supporting mechanism, so that the antenna mounting base 110 is protected better, and the antenna in the antenna mounting base 110 is prevented from being damaged; through the arrangement of the heat dissipating cylinder 930 in the cabinet body 810, heat generated in the cabinet cavity 910 can be transmitted to the water collecting cylinder 950 through the heat dissipating cylinder through hole 940, and is dissipated to the air through the heat dissipating circular plate 820 on the water collecting cylinder 950, meanwhile, the water collecting cylinder 950 can also collect rainwater in rainwater weather, and the cabinet cavity 910 is dissipated through the evaporation of water flow in the water collecting cylinder 950. When the 5G communication system in this embodiment is used, the antenna mounting base 110 can be better protected and the cabinet body 810 can be better cooled, so that the 5G communication system has better stability when in use.

In this embodiment, the supporting mechanism includes a mounting sleeve 230 respectively disposed on the inner wall of the upper end and the inner wall of the bottom end of the antenna mounting cavity 210 and located at the mounting seat through hole 220, the inner wall of the mounting sleeve 230 is larger than the aperture of the mounting seat through hole 220, the inner wall of the mounting sleeve 230 far away from the mounting seat through hole 220 is inwardly contracted to form an annular baffle 240, an upper sliding rod 250 and a lower sliding rod 260 which are slidable and hollow inside are respectively disposed in the mounting sleeve 230 at the upper end and the lower end of the antenna mounting cavity 210, and a connecting mechanism for connecting the upper sliding rod 250 and the lower sliding rod 260 is disposed between the upper sliding rod 250 and the lower; the ends of the upper sliding rod 250 and the lower sliding rod 260 adjacent to the ring-shaped baffle 240 are outwardly expanded along the circumferential direction thereof to form a sliding rod flange 270 which is spaced from the inner wall of the mounting sleeve 230; a damping spring 280 for pushing the upper sliding rod 250 and the lower sliding rod 260 into the mounting sleeve 230 is arranged in the mounting sleeve 230; the end portions of the upper sliding rod 250 and the lower sliding rod 260 extend out of the mounting seat through hole 220, the end portion of the upper sliding rod 250 extending out of the mounting seat through hole 220 is provided with an upper baffle 130, and the end portion of the lower sliding rod 260 extending out of the mounting seat through hole 220 is provided with a lower baffle 140.

When the antenna mounting base 110 in this embodiment is used, after the upper baffle 130 is impacted, the lower sliding rod moves downward 260 through the cooperation between the upper sliding rod 250 and the connection mechanism, and compresses the shock absorbing spring 280 below the lower sliding rod 260, so as to buffer the impact; after the lower baffle 260 is impacted, the upper sliding rod 250 moves upwards to compress the damping spring 280 above the upper sliding rod 250 through the cooperation between the lower sliding rod 260 and the connecting mechanism, so that the impact is buffered; through the arrangement of the supporting mechanism structure in the embodiment, the impact on the upper end portion and the lower end portion of the antenna mounting base 110 can be better buffered, so that the antenna mounting base 110 has better stability when in use.

In this embodiment, the upper and lower ends of the connecting mechanism both extend into the mounting sleeve 230, and the end of the connecting mechanism extending out of the mounting sleeve 230 is provided with a connecting mechanism flange 290 in clearance fit with the inner wall of the mounting sleeve 230; the upper sliding rod 250, the lower sliding rod 260 and the connecting mechanism are all hollow, the upper end of the upper sliding rod 250 is provided with a plurality of upper sliding rod through holes 2100 which are uniformly distributed, and the lower baffle 140 is provided with a lower baffle through hole 2110 which is communicated with the inner cavity of the lower sliding rod 260.

Through the hollow arrangement of the upper sliding rod 250, the lower sliding rod 260 and the connecting mechanism in the present embodiment, the heat in the antenna mounting cavity 210 can be transferred to the interiors of the upper sliding rod 250, the lower sliding rod 260 and the connecting mechanism, and discharged through the upper sliding rod through hole 2100 and the lower baffle through hole 2110, so that the antenna mounting base 110 in the present embodiment has a better heat dissipation function.

In this embodiment, an upper surrounding plate 150 perpendicular to the upper baffle 130 and in clearance fit with the antenna mounting base 110 is disposed on a lower end surface of the upper baffle 130, and a plurality of upper surrounding plate through holes 160 are disposed on the upper surrounding plate 150.

Through the arrangement of the upper surrounding plate 150 in this embodiment, dust and rainwater in the external environment can be preferably prevented from entering the upper sliding rod 250 through the upper sliding rod through hole 2100, and entering the antenna mounting cavity 210 through the upper sliding rod 250, so that the stability of the antenna mounting base 110 in this embodiment in use is preferably improved.

In this embodiment, the upper end surface of the antenna mounting base 110 at the end of the mounting base through hole 220 protrudes upward to form an annular boss 2120.

Through the arrangement of the annular boss 2120 in this embodiment, rainwater in the external environment can be better prevented from entering the antenna mounting cavity 210 through the mounting seat through hole 220, so that the stability of the antenna mounting seat 110 in this embodiment in use is better improved.

In this embodiment, the middle of the antenna mounting base 110 is provided with an air inlet 2130 communicated with the antenna mounting cavity 210, the middle of the antenna mounting cavity 210 is provided with a connecting mechanism mounting base 2140, the connecting mechanism mounting base 2140 is provided with a cylindrical connecting mechanism mounting cavity 2150, the antenna mounting cavity 210 is provided with a connecting pipe 2160 for communicating the connecting mechanism mounting cavity 2150 with the air inlet 2130, and the connecting pipe 2160 is provided with an antenna fan 2170; the connecting mechanism comprises an upper connecting sleeve 2180 and a lower connecting sleeve 2190, the lower end part of the upper connecting sleeve 2180 and the upper end part of the lower connecting sleeve 2190 both extend into the connecting mechanism mounting cavity 2150, and sleeve flanges 310 in clearance fit with the connecting mechanism mounting cavity 2150 are arranged at the adjacent ends between the upper connecting sleeve 2180 and the lower connecting sleeve 2190; the upper and lower sleeves 2180, 2190 are provided with a sleeve bore 410 which is located in the coupler mount 2150.

When the antenna mounting base 110 in this embodiment is used and the temperature in the antenna mounting cavity 210 is high, the antenna blower 2170 is activated, so that air enters from the air inlet 2130, enters the upper connection sleeve 2180 and the lower connection sleeve 2190 through the connection sleeve through hole 410, and is then discharged through the upper sliding rod through hole 2100 and the lower baffle through hole 2110, so as to take away heat in the upper sliding rod 250, the lower sliding rod 260, the upper connection sleeve 2180 and the lower connection sleeve 2190, thereby cooling the antenna mounting cavity 210. In this embodiment, through the setting of antenna fan 2170 and coupling mechanism mount 2140, can be the preferred cool down to antenna installation cavity 210 to when cooling down to antenna installation cavity 210, the air does not contact with the electrical components in antenna installation cavity 210, thereby the dust is piled up and is leaded to electrical components to break down in antenna installation cavity 210 in having avoided external environment of preferred, the promotion of preferred this antenna mount 110 stability when using.

In this embodiment, the upper end of the antenna mounting base 110 is provided with a hinge base 170, the edge of the lower baffle 140 is provided with a connecting rod mounting base 2200, a connecting rod 180 capable of rotating along the connecting rod mounting base 2200 is arranged in the connecting rod mounting base 2200, and an anchor ear 190 is arranged at the end of the connecting rod 180 far away from the connecting rod mounting base 2200; a rotatable gear mounting shaft 420 is arranged in the connecting pipe 2160, a first bevel gear 430 is arranged at the end of a rotating shaft on the antenna fan 2170, a second bevel gear 440 meshed with the first bevel gear 430 is arranged in the middle of the gear mounting shaft 420, a mounting shaft flange 510 is arranged at the lower end of the gear mounting shaft 420, a mounting shaft lower gear 450 is arranged on the mounting shaft flange 510, a flange mounting cavity 520 is arranged in the mounting shaft lower gear 450, the mounting shaft flange 510 is arranged in the flange mounting cavity 520, a ratchet groove 530 circumferentially arranged along the flange mounting cavity 520 is arranged on the inner wall of the flange mounting cavity 520, and a locking claw 540 matched with the ratchet groove 530 is arranged on the mounting shaft flange 510; the lower coupling sleeve 2190 has a lower coupling sleeve gear 460 disposed below the coupling sleeve aperture 410 and engaged with the lower mounting shaft gear 450.

When the antenna mount 110 of the present embodiment is mounted, the hinge base 170 of the upper end portion of the antenna mount 110 is mounted on the antenna mounting pole 1100, and then the annular mounting groove 1101 is provided on the antenna mounting pole 1100, and the anchor ear 190 is mounted in the annular mounting groove 1101 such that the anchor ear 190 can rotate in the annular mounting groove 1101. When the angle of the antenna mounting base 110 needs to be adjusted, the antenna fan 2170 can be driven to rotate reversely, the mounting shaft lower gear 450 rotates along with the rotation of the gear mounting shaft 420 through the matching of the ratchet groove 530 and the stop pawl 540, the lower connecting sleeve 2190 rotates through the matching between the mounting shaft lower gear 450 and the connecting sleeve lower gear 460, the lower baffle 140 on the lower connecting sleeve 2190 rotates along with the rotation of the lower connecting sleeve 2190, the distance between the connecting rod mounting base 2200 on the lower baffle 140 and the antenna mounting rod 1100 changes, and the adjustment of the angle of the antenna mounting base 110 is realized through the matching of the connecting rod 180 on the connecting rod mounting base 2200. In this embodiment, through the cooperation between installation axle lower gear 450 and connecting sleeve lower gear 460, comparatively convenient realization to the regulation of antenna mount pad 110 angle to avoided after the antenna mount pad 110 installation finishes, installer need climb to the upper end of antenna installation pole 1100 and adjusted the angle of antenna mount pad 110, thereby both the reduction of preferred installer's intensity of labour, the protection of installer's safety that has preferred again.

In this embodiment, the antenna installation cavity 210 is provided with two slide rails 320, a rotatable lead screw 330 is arranged between the two slide rails 320, and the antenna installation cavity 210 is provided with a driving mechanism for driving the lead screw 330; the screw 330 is provided with a screw slider 340 in a matching way, the bottom end of the antenna mounting seat 110 is provided with a strip-shaped antenna outlet 350, and the lower baffle 140 is provided with a lower baffle through hole 141 in a matching way with the antenna outlet 350; the lead screw slider 340 is provided with an antenna mounting plate 360 for mounting an antenna, and the lower end of the antenna mounting plate 360 is provided with an outlet baffle 370 for matching with the antenna outlet 350.

When the antenna mounting base 110 in this embodiment is used and an antenna in the antenna mounting cavity 210 needs to be maintained, the driving mechanism can be started, the antenna mounting plate 360 slides out of the antenna mounting cavity 210 through the cooperation between the screw 330 and the screw slider 340, and after the antenna is maintained, the driving mechanism can be started, and the antenna mounting plate 360 is retracted into the antenna mounting cavity 210 through the cooperation between the screw 330 and the screw slider 340. In this embodiment, through the cooperation between the lead screw 330 and the lead screw slider 340, when performing maintenance on the antenna in the antenna installation cavity 210, a maintenance person does not need to take the antenna installation base 110 off the antenna installation rod 1100 and open the antenna installation base 110 to maintain the antenna, so that the maintenance on the antenna in the antenna installation cavity 210 is more conveniently achieved, and the labor intensity of the maintenance person is preferably reduced.

In this embodiment, the driving mechanism includes a screw gear 610 disposed at the upper end of the screw 330, a rotatable gear mounting rod 620 is disposed in the antenna mounting cavity 210, and an upper end of the gear mounting rod 620 is provided with an upper mounting rod gear 630 engaged with the screw gear 610; the lower end of the gear mounting rod 620 is provided with a mounting rod lower gear 640, and the upper connecting sleeve 2180 is provided with a connecting sleeve upper gear 380 which is positioned between the mounting sleeve 230 and the connecting mechanism mounting seat 2140 and is meshed with the mounting rod lower gear 640; the gear mounting shaft 420 has a mounting shaft upper gear 470 at an upper end thereof, and the sleeve flange 310 of the upper coupling sleeve 2180 has a rack 710 engaged with the mounting shaft upper gear 470.

When the antenna mounting base 110 in this embodiment is used, the upper baffle 130 can be pulled upwards and the upper baffle 130 is limited by the pin shaft penetrating through the upper baffle through hole 160, at this time, the upper connecting sleeve 2180 moves upwards under the action of the damping spring 280 below the lower sliding rod 260, the rack 710 on the upper connecting sleeve 2180 is engaged with the upper gear 470 on the mounting shaft, at this time, the antenna fan 2170 is driven, so that the upper connecting sleeve 2180 rotates along with the rotation of the gear mounting shaft 420, the gear mounting rod 620 rotates through the matching between the upper gear 380 on the connecting sleeve and the lower gear 640 on the gear mounting rod, and the rotation of the screw rod 330 is realized through the matching between the upper gear 630 on the mounting rod and the screw rod gear 610, so that the driving of the screw rod 330 is realized. In this embodiment, the arrangement of the driving mechanism structure enables the antenna fan 2170 in this embodiment to not only cool the antenna installation cavity 210, but also drive the lead screw 330 better.

In this embodiment, the bottom end of the upper coupling sleeve 2180 is provided with a limiting flange 480 that is located in the coupling mechanism mounting cavity 2150 and is located at the upper end of the coupling sleeve through hole 410.

Through the arrangement of the limiting flange 480 in the embodiment, not only can the phenomenon that the rack 710 is disengaged from the upper gear 470 on the mounting shaft due to the overlarge ascending distance of the upper connecting sleeve 2180 be avoided, but also the phenomenon that dust in the outside air enters the antenna mounting cavity 210 due to the contact between the connecting sleeve through hole 410 and the antenna mounting cavity 210 is avoided.

In this embodiment, a heat dissipating shroud 830 perpendicular to the heat dissipating circular plate 820 is disposed at an edge of an upper end surface of the heat dissipating circular plate 820, and a water collecting groove 840 is formed between the heat dissipating circular plate 820 and the heat dissipating shroud 830.

Through the arrangement of the heat dissipation shroud 830 in this embodiment, it is able to form the water collecting tank 840 with the heat dissipation circular plate 820 so that rainwater can flow into the water collecting cylinder 950 better, and when heat dissipation is performed on the cabinet body 810, water flow can be attached to the heat dissipation shroud 830 to take away heat on the heat dissipation shroud 830, thereby improving the heat dissipation effect better.

In this embodiment, the water collection tank 840 is provided with strip-shaped heat dissipation plates 850 distributed along the circumferential direction of the heat dissipation cylinder 930.

Through the arrangement of the strip-shaped heat dissipation plate 850 in this embodiment, the heat dissipation area of the heat dissipation circular plate 820 can be increased, so that the heat dissipation effect is improved.

In this embodiment, the inner wall of the water collecting cylinder 950 is provided with a plurality of uniform capillaries 860, and the upper ends of the capillaries 860 extend into the water collecting tank 840.

Through the arrangement of the capillary tube 860 in this embodiment, the water flow in the water collecting cylinder 950 moves to the heat dissipating circular plate 820 due to the capillary phenomenon, and the water flow on the heat dissipating circular plate 820 takes away the heat on the heat dissipating circular plate 820 through evaporation, thereby better enhancing the heat dissipating effect on the cabinet body 810.

In this embodiment, the end of the heat dissipating cylinder 930 extending out of the cabinet cavity 910 is provided with a rotating plate 870 located below the heat dissipating circular plate 820, and a plurality of wind blocking plates 880 circumferentially distributed along the heat dissipating cylinder 930 are disposed between the rotating plate 870 and the heat dissipating circular plate 820; the upper end surface of the cabinet body 810 is located at the end of the upper through hole 920 of the cabinet and protrudes upwards to form an upper boss 960 of the cabinet, and the edge of the lower end surface of the rotating plate 870 is provided with a lower enclosing plate 970 of the rotating plate.

Through the arrangement of the wind-blocking plate 880 in this embodiment, when wind exists, the heat-dissipating cylinder 930 can be rotated through the wind-blocking plate 880, so that water flow on the heat-dissipating circular plate 820 can be uniformly distributed on the heat-dissipating circular plate 820, and the water-collecting cylinder 950 can be rotated along with the rotation of the heat-dissipating cylinder 930, so that the water flow in the water-collecting cylinder 950 can be conveniently moved to the heat-dissipating circular plate 820, thereby improving the heat-dissipating effect of the cabinet body 810.

In this embodiment, a spring installation cylinder 980 located right below the heat dissipation cylinder 930 is arranged at the bottom end of the cabinet cavity 910, the inner wall of the upper end of the spring installation cylinder 980 is inwardly contracted to form an installation cylinder flange 990, the lower end of the heat dissipation cylinder 930 extends into the spring installation cylinder 980, a heat dissipation cylinder flange 1010 in clearance fit with the inner wall of the spring installation cylinder 980 is arranged at the end of the heat dissipation cylinder 930 extending into the spring installation cylinder 980, and a support spring 9100 located below the heat dissipation cylinder flange 1010 and used for supporting the heat dissipation cylinder 930 is arranged in the spring installation cylinder 980; the side walls at the two ends of the cabinet body 810 are respectively provided with a plurality of cabinet heat dissipation holes 9110 arranged along the height direction of the cabinet body, the inner wall of the cabinet cavity 910 is provided with two guide rails 1110 respectively positioned at the two ends of the cabinet heat dissipation holes 9110, the two guide rails 1110 are respectively provided with a guide rail slider 1120 arranged along the length direction of the guide rails 1110, and a plurality of sealing strips 1130 used for sealing the cabinet heat dissipation holes 9110 are arranged between the two guide rail sliders 1120; a connecting rod 1140 connected with the two guide rail sliders 1120 is arranged between the guide rail sliders 1120 at the two ends of the cabinet cavity 910, a limiting frame 9120 is arranged between the two connecting rods 1140, the limiting frame 9120 comprises a limiting rod 1150 connected with the connecting rod 1140, a limiting ring 1160 which is sleeved at the middle part of the heat radiating cylinder 930 and is in clearance fit with the heat radiating cylinder 930 is arranged between the two limiting rods 1150, and two limiting flanges 9130 which are respectively positioned at the upper end and the lower end of the limiting ring 1160 and are matched with the limiting ring 1160 are arranged on the outer side wall of the heat radiating cylinder 930.

When the cabinet body 810 in this embodiment is in operation, after the water flow in the water collecting cylinder 950 is evaporated, the heat radiating cylinder 930 and the water collecting cylinder 950 move upward together, and due to the matching between the limiting frame 9120 and the limiting flange 9130 on the heat radiating cylinder 930, the limiting frame 9120 moves along with the movement of the heat radiating cylinder 930, so that the guide rail slider 1120 moves upward, the sealing strip 1130 moves to the upper side of the cabinet heat radiating hole 9110, and the heat in the cabinet cavity 910 is discharged from the cabinet heat radiating hole 9110; in rainy days, after a certain amount of water flow is accumulated in the water collecting cylinder 950, the water collecting cylinder 950 and the heat radiating cylinder 930 move downwards together, so that the sealing strip 1130 seals the heat radiating holes 9110 of the cabinet, and rainwater is prevented from entering the cabinet cavity 910. In this embodiment, through the cooperation between the guide rail 1110, the guide rail slider 1120, the cabinet heat dissipation hole 9110 and the sealing strip 1130, heat dissipation of the cabinet cavity 910 is preferably achieved, and rainwater in an external environment is prevented from entering the cabinet cavity 910.

In this embodiment, the bottom end of the cabinet body 810 is provided with a cabinet lower through hole 1020, the bottom end of the cabinet body 810 is provided with a fan mounting seat 890 positioned at the cabinet lower through hole 1020, a cabinet fan 9140 is arranged in the fan mounting seat 890, and the fan mounting seat 890 is provided with an air inlet hole 9150; a displacement sensor for detecting the moving distance of the heat dissipation cylinder 930 is arranged on the outer side wall of the heat dissipation cylinder 930.

Cabinet body 810 in this embodiment is when using, after rivers evaporation in the water catch bowl 950 is done, heat dissipation cylinder 930 moves on with water catch bowl 950 under supporting spring 9100's effect, displacement sensor detects the displacement volume of heat dissipation cylinder 930, displacement sensor is connected with the PLC controller and is used for carrying out the power that supplies power to displacement sensor and PLC controller, upwards remove a certain amount after heat dissipation cylinder 930, PLC control cabinet fan 9140 operation, make the outside air get into from intake opening 9150, via fan mount pad 890, spring-mounted cylinder 980, heat dissipation cylinder through-hole 940 gets into in cabinet chamber 910, discharge by cabinet louvre 9110 at last, thereby realize the heat dissipation to cabinet chamber 910. When a certain amount of water flow is accumulated in the water collection cylinder 950, the PLC controller controls the cabinet fan 9140 to stop working. In this embodiment, through the arrangement of the cabinet blower 9140 and the displacement sensor, the heat dissipation of the cabinet cavity 910 is preferably realized, and the automation control of the cabinet blower 9140 is realized, so that the cabinet blower 9140 is automatically closed when the temperature is low, and thus the heat dissipation of the cabinet cavity 910 is preferably realized, and the resources are preferably saved.

In this embodiment, the lower end of the heat dissipating cylinder 930 is open, the lower end of the water collecting cylinder 950 passes through the lower cabinet through hole 1020 and extends into the fan mounting seat 890, a limiting plate 1030 for limiting the water collecting cylinder 950 is arranged in the lower cabinet through hole 1020, a limiting plate through hole 1210 in clearance fit with the water collecting cylinder 950 is arranged on the limiting plate 1030, and a plurality of air inlet through holes 1220 are arranged on the limiting plate 1030 along the circumferential direction of the limiting plate through hole 1210; a third bevel gear 9160 is arranged at the end part of the rotating shaft of the cabinet fan 9140, a fourth bevel gear 9170 matched with the third bevel gear 9160 is arranged at the bottom end part of the water collecting cylinder 950, and a thermal expansion gasket 10100 positioned at the lower end of the supporting spring 9100 is arranged in the spring mounting cylinder 980; the upper end of the cabinet body 810 is provided with a water delivery pipe 8100 for delivering water to the water collection tank 840, and the end of the water delivery pipe 8100 is connected with a water pump.

When the cabinet body 810 in this embodiment is used, when the heat in the cabinet cavity 910 cannot be discharged under the action of the cabinet blower 9140, along with the accumulation of the temperature in the cabinet cavity 910, the thermal expansion gasket 10100 is increased to lift the supporting spring 9100, when the displacement sensor detects that the heat dissipating cylinder 930 continues to lift and sends a signal to the PLC controller, the PLC controller controls the operation of the water pump, so that the water flows to the heat dissipating circular plate through the water pump via the water pipe 8100, at this time, due to the lift of the water collecting cylinder 950, the third bevel gear 9160 is engaged with the fourth bevel gear 9170, so that the water collecting cylinder 950 rotates along with the rotation of the cabinet blower 9140, and not only the water falling into the water collecting tank 840 can be more uniformly distributed on the heat dissipating circular plate 820, the heat dissipating coaming 830 and the strip-shaped heat dissipating plate 850, the heat dissipating effect is better improved, but also due to the rotation of the heat dissipating cylinder 930, the air flowing out of the heat dissipation cylinder through hole 940 flows to all places in the cabinet cavity 910, so that the heat dissipation effect on the cabinet cavity 910 is better improved; when a certain amount of water flow is accumulated in the water collecting cylinder 950, the water collecting cylinder 950 and the heat radiating cylinder 930 move downward, and the PLC control cabinet motor 9140 is turned off. In this embodiment, through the setting of water pump and thermal expansion gasket 10100, further promoted the radiating effect of rack body 810, avoided the temperature in rack body 810 too high and lead to the damage of electrical components in rack body 810 to the better stability of rack body 810 when the operation that has promoted.

In this embodiment, be equipped with the first annular bounding wall 1040 that is located through-hole 1020 department under the rack in the spring mounting section of thick bamboo 980, the outside of first annular bounding wall 1040 is equipped with second annular bounding wall 1050, constitute sleeve installation cavity 1060 between first bounding wall 1040 and the second bounding wall 1050 jointly, be equipped with slidable support cylinder 1070 in the sleeve installation cavity 1060, sleeve installation cavity 1060 is stretched out to the upper end of support cylinder 1070, the tip that stretches out sleeve installation cavity 1060 on the support cylinder 1070 is equipped with support cylinder flange 1080, the upper end of support spring 9100 supports and leans on support cylinder flange 1080.

By the arrangement of the supporting cylinder 1070 and the supporting cylinder flange 1080 in this embodiment, the supporting spring 9100 is prevented from directly contacting the heat-dissipating cylinder flange 1010, so that the friction force applied to the heat-dissipating cylinder 930 during rotation is preferably reduced.

In this embodiment, a spring installation cavity 1090 is formed between the second enclosing plate 1050 and the spring installation cylinder 980 together, and the supporting spring 9100 is disposed in the spring installation cavity 1090.

Through the arrangement of the spring installation cavity 1090 in the embodiment, the support spring 9100 can be conveniently installed.

In summary, the above-mentioned embodiments are only preferred embodiments of the present invention, and all equivalent changes and modifications made in the claims of the present invention should be covered by the claims of the present invention.

Claims (10)

1. A base station device for 5G communication, comprising: including rack body (810), be equipped with rack chamber (910) in rack body (810), through-hole (920) on the rack is established to the upper end of rack body (810), be equipped with in rack chamber (910) with rack on through-hole (920) clearance fit's radiating cylinder (930), be equipped with a plurality of evenly distributed's radiating cylinder through-hole (940) on radiating cylinder (930), be equipped with upper end open-ended water catch bowl (950) in radiating cylinder (930), through-hole (920) on the rack is stretched out to the upper end of water catch bowl (950), the tip that stretches out through-hole (920) on the rack on water catch bowl (950) is equipped with heat dissipation plectane (820), the upper end heat dissipation plectane (820) of radiating cylinder (930) are connected.

2. The base station apparatus for 5G communication according to claim 1, wherein: the edge of the upper end face of the heat dissipation circular plate (820) is provided with a heat dissipation enclosing plate (830) perpendicular to the heat dissipation circular plate (820), and a water collecting tank (840) is formed between the heat dissipation circular plate (820) and the heat dissipation enclosing plate (830) together.

3. The base station apparatus for 5G communication according to claim 2, wherein: the water collecting tank (840) is internally provided with strip-shaped heat dissipation plates (850) which are distributed along the circumferential direction of the heat dissipation cylinder (930).

4. The base station apparatus for 5G communication according to claim 2, wherein: the inner wall of the water collecting cylinder (950) is provided with a plurality of uniform capillaries (860), and the upper end parts of the capillaries (860) extend into the water collecting tank (840).

5. The base station apparatus for 5G communication according to claim 1, wherein: a rotating plate (870) positioned below the heat dissipation circular plate (820) is arranged at the end part of the heat dissipation cylinder (930) extending out of the cabinet cavity (910), and a plurality of wind blocking plates (880) distributed along the circumferential direction of the heat dissipation cylinder (930) are arranged between the rotating plate (870) and the heat dissipation circular plate (820); the upper end face of the cabinet body (810) is located at the end part of the upper through hole (920) of the cabinet and protrudes upwards to form an upper boss (960) of the cabinet, and the edge of the lower end face of the rotating plate (870) is provided with a lower rotating plate enclosing plate (970).

6. The base station apparatus for 5G communication according to claim 1, wherein: a spring installation cylinder (980) located right below the heat dissipation cylinder (930) is arranged at the bottom end of the cabinet cavity (910), the inner wall of the upper end of the spring installation cylinder (980) is inwardly contracted to form an installation cylinder flange (990), the lower end of the heat dissipation cylinder (930) extends into the spring installation cylinder (980), a heat dissipation cylinder flange (1010) in clearance fit with the inner wall of the spring installation cylinder (980) is arranged at the end part of the heat dissipation cylinder (930) extending into the spring installation cylinder (980), and a supporting spring (9100) located below the heat dissipation cylinder flange (1010) and used for supporting the heat dissipation cylinder (930) is arranged in the spring installation cylinder (980); the cabinet heat dissipation device is characterized in that a plurality of cabinet heat dissipation holes (9110) are formed in the side walls of two ends of the cabinet body (810) in the height direction of the cabinet body, two guide rails (1110) which are respectively located at two ends of each cabinet heat dissipation hole (9110) are arranged on the inner wall of the cabinet cavity (910), guide rail sliding blocks (1120) which are arranged in the length direction of the guide rails (1110) are arranged on the two guide rails (1110), and a plurality of sealing strips (1130) used for sealing the cabinet heat dissipation holes (9110) are arranged between the two guide rail sliding blocks (1120); be equipped with connecting rod (1140) of connecting two rail blocks (1120) between rail block (1120) at both ends in rack chamber (910), be equipped with spacing (9120) between two connecting rod (1140), spacing (9120) include gag lever post (1150) that are connected with connecting rod (1140), be equipped with between two gag lever posts (1150) and cup joint in heat-dissipating cylinder (930) middle part and with heat-dissipating cylinder (930) clearance fit's spacing ring (1160), be equipped with two on the lateral wall of heat-dissipating cylinder (930) and be located respectively spacing ring (1160) upper and lower extreme and with spacing ring (1160) matched with spacing flange (9130).

7. The base station apparatus for 5G communication according to claim 6, wherein: a lower cabinet through hole (1020) is formed in the bottom end of the cabinet body (810), a fan mounting seat (890) located at the lower cabinet through hole (1020) is formed in the bottom end of the cabinet body (810), a cabinet fan (9140) is arranged in the fan mounting seat (890), and an air inlet hole (9150) is formed in the fan mounting seat (890); and a displacement sensor for detecting the moving distance of the heat dissipation cylinder (930) is arranged on the outer side wall of the heat dissipation cylinder (930).

8. The base station apparatus for 5G communication according to claim 7, wherein: the lower end part of the heat dissipation cylinder (930) is opened, the lower end part of the water collection cylinder (950) penetrates through the lower through hole (1020) of the machine cabinet and extends into the fan mounting seat (890), a limiting plate (1030) used for conducting clearance fit on the water collection cylinder (950) is arranged in the lower through hole (1020) of the machine cabinet, a limiting plate through hole (1210) in clearance fit with the water collection cylinder (950) is arranged on the limiting plate (1030), and a plurality of air inlet through holes (1220) are formed in the limiting plate (1030) and are circumferentially arranged along the limiting plate through hole (1210; the tip of rack fan (9140) pivot is equipped with third bevel gear (9160), the bottom portion of water-collecting drum (950) is equipped with fourth bevel gear (9170) with third bevel gear (9160) matched with, be equipped with thermal expansion gasket (10100) that are located supporting spring (9100) lower extreme in spring-mounted cylinder (980), the upper end of rack body (810) is equipped with and is used for carrying out defeated raceway (8100) of water to water catch bowl (840), the end connection of raceway (8100) has the water pump.

9. The base station apparatus for 5G communication according to claim 6, wherein: be equipped with first annular bounding wall (1040) that is located through-hole (1020) department under the rack in spring mounting section of thick bamboo (980), the outside of first annular bounding wall (1040) is equipped with second annular bounding wall (1050), constitute sleeve installation cavity (1060) between first bounding wall (1040) and second bounding wall (1050) jointly, be equipped with slidable support section of thick bamboo (1070) in sleeve installation cavity (1060), sleeve installation cavity (1060) are stretched out to the upper end of support section of thick bamboo (1070), the tip that stretches out sleeve installation cavity (1060) on support section of thick bamboo (1070) is equipped with support section of thick bamboo flange (1080), the upper end of support spring (9100) supports and leans on support section of thick bamboo flange (1080).

10. The base station apparatus for 5G communication according to claim 9, wherein: a spring mounting cavity (1090) is formed between the second enclosing plate (1050) and the spring mounting cylinder (980), and the supporting spring (9100) is arranged in the spring mounting cavity (1090).

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