CN113890479B - 5G base station power supply system based on sharing is filled and is traded electric cabinet - Google Patents

Abstract

The invention discloses a 5G base station power supply system based on a shared charging and converting cabinet, which comprises a fixed part, a dust collector and a gas booster, wherein a rotating part is rotatably arranged on the fixed part, an adjusting part is rotatably arranged on the rotating part, a hydraulic cylinder is rotatably arranged on the rotating part, a control part is arranged on the adjusting part, first power generating parts which are symmetrically distributed are rotatably arranged on the adjusting part, a telescopic cylinder is arranged on the first power generating parts, and a second power generating part is slidably arranged on the first power generating parts. The power supply system has two power supply modes, and the power supply modes are switched by setting a threshold interval; the power supply system has high flexibility, and can adjust the irradiation angle according to the light angle, thereby improving the light utilization rate; the power supply system has extreme weather resistance, detects the wind direction through the wind direction sensor, folds the power generation part into an angle shape, and reduces the wind resistance; the power supply system has a self-dedusting function, the influence of dust on the solar panel on illumination is reduced, and the illumination utilization rate is improved.

Description

5G base station power supply system based on sharing is filled and is traded electric cabinet

Technical Field

The invention relates to a base station power supply system, in particular to a 5G base station power supply system based on a shared charging and converting cabinet.

Background

With the development of the digital era, people have higher and higher dependence on networks, particularly mobile communication. With the development of communication technology, a fifth generation mobile communication network (5G network) has become a reality from the concept, the communication capability is significantly improved by 5G access, and the transmission rate and the access capability of the 5G network are improved by 100 times in terms of high reliability and low latency compared with the 4G network, and the network latency is shortened to 1/100. The world has entered the commercial stage, which requires the construction of a large number of 5G base stations.

The 5G base station is as the indispensable facility of receiving and dispatching signals of sharing charging and exchanging electricity cabinet, because 5G base station deployment density is greater than the 4G base station, and 5G base station's power consumption is huge moreover, and low use frequency at night greatly wastes electric power, consequently, the power supply value of building 5G base station is worth emphatically considering.

Disclosure of Invention

The invention aims to provide a 5G base station power supply system based on a shared charging and converting cabinet, wherein a first signal transceiver, a second signal transceiver and a third signal transceiver are installed, a motor drives a screw rod to rotate, a control plate and a connecting plate are driven to move through screw-thread fit transmission, a rotating frame is further driven to rotate, a first solar panel on the first transceiver is driven to rotate and expand, an output shaft of a telescopic cylinder drives a second power generation part to move, the second solar panel and the first solar panel are relatively expanded, an eighth connecting hole is communicated with a fourth connecting hole, a sixth connecting hole is communicated with the second connecting hole, a hydraulic cylinder drives an adjusting part to rotate according to a light angle detected by a photoelectric sensor, the first solar panel and the second solar panel are further driven to rotate, sunlight is vertically irradiated on the solar panels, heat loss is reduced, light conversion efficiency is improved, electric power is stored in a storage battery, during dust removal, a gas supercharger blows high-pressure gas out from a first air hole and a second air hole, dust collector on the first solar panels and the second solar panels is cleaned, and dust collector is started after dust is blown out; the power supply system has two power supply modes, a time threshold interval with high utilization rate and a time threshold interval with low utilization rate are set through the use frequency of the power supply cabinet, the power supply system is in high utilization rate time and has high power consumption, the power supply station directly transmits power to carry out power supply and signal transmission on the shared charging cabinet, and the power supply system is in low utilization rate time and carries out power supply and signal transmission through the power stored in the storage battery by solar energy; the power supply system has high flexibility, and can adjust the irradiation angle according to the light angle, thereby improving the light utilization rate; the power supply system has extreme weather resistance, detects the wind direction through the wind direction sensor, folds the power generation part into an angle shape, and reduces the wind resistance; the power supply system has a self-dedusting function, the influence of dust on the solar panel on illumination is reduced, and the illumination utilization rate is improved.

The purpose of the invention can be realized by the following technical scheme:

the utility model provides a 5G basic station power supply system based on sharing is charged and is traded electric cabinet, power supply system includes mounting (1), dust arrester and gas booster compressor, it is equipped with and rotates piece (2) to rotate on mounting (1), it is equipped with regulating part (3) to rotate on rotating piece (2), it is equipped with pneumatic cylinder (4) to rotate on rotating piece (2), be equipped with control (5) on regulating part (3), it is equipped with first power generation spare (6) of symmetric distribution to rotate on regulating part (3), be equipped with telescoping cylinder (7) on first power generation spare (6), it is equipped with second power generation spare (8) to slide on first power generation spare (6), the output shaft and second power generation spare (8) the fastening connection of telescoping cylinder (7).

Further, mounting (1) is including fixed column (11), be equipped with first signal transceiver (12) on fixed column (11), be equipped with second signal transceiver (13) on fixed column (11), be equipped with third signal transceiver (14) on fixed column (11), be equipped with mount (15) on fixed column (11), be equipped with guide bar (16) on mount (15), be equipped with first driving piece (19) on fixed column (11), first signal transceiver (12), second signal transceiver (13) and third signal transceiver (14) all with mount (15) sliding connection.

The first signal receiving and transmitting part (12) comprises a signal receiving and transmitting part (121), a first connecting rod (122) is arranged on the signal receiving and transmitting part (121) in a rotating mode, a first sliding block (123) is arranged on the first connecting rod (122) in a rotating mode, the first sliding block (123) is connected with the fixed frame (15) in a sliding mode, a first guide groove (124) is formed in the first sliding block (123), and the first guide groove (124) is matched with the guide rod (16) in a sliding mode.

And a second connecting rod (125) is arranged on the signal transceiver (121) in a rotating manner, a second sliding block (126) is arranged on the second connecting rod (125) in a sliding manner, and a third connecting rod (127) is arranged on the signal transceiver (121) in a rotating manner.

Second connecting rod (125) include connecting rod body (1251), are equipped with spacing groove (1252) on connecting rod body (1251), are equipped with fixed block (1254) on connecting rod body (1251), are equipped with second guide way (1255) on fixed block (1254), fixed block (1254) and mount (15) sliding connection, second guide way (1255) and guide bar (16) sliding fit.

Furthermore, the first signal transceiver (12), the second signal transceiver (13) and the third signal transceiver (14) have the same structure and the same connection mode, and the difference is that the signal transceiver (121) on the first signal transceiver (12), the second signal transceiver (13) and the third signal transceiver (14) has different signal transceiving directions.

The first driving part (19) comprises a first fixing box (191) and a first gear (192), a rotating shaft (193) is arranged on the first gear (192), a motor is arranged in the first fixing box (191), and an output shaft of the motor penetrates through the first fixing box (191) to be fixedly connected with the rotating shaft (193).

Further, the rotating part (2) comprises a rotating column (21), a second gear (22) is arranged on the rotating column (21), a ninth through hole (23) is formed in the rotating column (21), the hydraulic cylinder (4) is rotatably connected with the inner wall of the ninth through hole (23), a rotating shaft hole (24) is formed in the rotating column (21), a wind direction sensor (25) is arranged on the rotating column (21), the rotating column (21) is rotatably connected with the fixing column (11), and the second gear (22) is in meshing transmission with the first gear (192).

Further, regulating part (3) includes support frame (31), support frame (31) are equipped with dwang (32), regulating part (3) are connected with rotating a piece (2) and rotate through dwang (32) and pivot hole (24) cooperation, be equipped with fixed case (33) of second on support frame (31), be equipped with the motor in the fixed case (33) of second, it is equipped with lead screw (34) to rotate on support frame (31), the output shaft of motor passes fixed case (33) of second and is connected with lead screw (34) fastening, be equipped with fixed plate (35) on support frame (31), lead screw (34) are connected with fixed plate (35) rotation, be equipped with guide post (36) on fixed plate (35), be equipped with symmetrically distributed's hang plate (37) on fixed plate (35), be equipped with photoelectric sensor (38) on hang plate (37), be equipped with tenth through hole (39) on support frame (31), tenth through hole (39) and rotation post (21) sliding fit, the output shaft and support frame (31) of pneumatic cylinder (4) are connected with rotation.

Furthermore, control piece (5) include control panel (51), rotate on control panel (51) and be equipped with symmetric distribution's connecting plate (52), are equipped with screw hole (53) on control panel (51), lead screw (34) and screw hole (53) screw-thread fit, control panel (51) and guide post (36) sliding connection.

Further, the first power generation part (6) comprises a rotating frame (61), a first solar panel (62) is arranged on the rotating frame (61), a support plate (63) which is symmetrically distributed is arranged on the rotating frame (61), a sliding groove (64) is arranged on the support plate (63), first air holes (65) are distributed on the support plate (63) in an array manner, first dust absorption holes (66) are distributed on the support plate (63) in an array manner, the first air holes (65) and the first dust absorption holes (66) are distributed at intervals, a first connecting hole (67) is arranged in the support plate (63), the first connecting hole (67) is communicated with the first air hole (65), a second connecting hole (68) is communicated on the first air hole (65) at the end part of the support plate (63), the first connecting hole (67) is communicated with the second connecting hole (68), one end of the second connecting hole (68) is connected with a gas booster through a connecting pipe, the other end of the second connecting hole (68) is communicated with the sliding groove (64), the connecting plate (52) is rotatably connected with the rotating frame (61), a third connecting hole (63) is arranged on the support plate (63), a fourth connecting hole (691) is communicated with a fourth connecting hole (692), one end of the fourth connection hole (692) is connected to the dust collector through a connection pipe, and the other end of the fourth connection hole (692) is communicated with the chute (64).

Furthermore, the second power generation part (8) comprises a sliding frame (81) and sliding plates (82) which are symmetrically distributed, a second solar panel (83) is arranged between the sliding plates (82) which are symmetrically distributed, second dust suction holes (84) are distributed on the sliding plates (82) in an array manner, second air holes (85) which are distributed on the sliding plates (82) in an array manner, fifth connecting holes (86) are formed in the sliding plates (82), the fifth connecting holes (86) are communicated with the second dust suction holes (84), sixth connecting holes (87) are communicated with the sliding plates (82), the sixth connecting holes (87) are communicated with the fifth connecting holes (86), second air holes (85) which are distributed in an array manner are formed in the sliding plates (82), seventh connecting holes (88) are formed in the sliding plates (82), the seventh connecting holes (88) are communicated with the second air holes (85), eighth connecting holes (89) are communicated with the seventh connecting holes (88), the second power generation part (8) is matched with the second power generation part (6) through a sliding chute (64), the second power generation part (7) is connected with the sliding frame (7) in a sliding manner, and the telescopic cylinder (83) and the telescopic cylinder (7) is connected with the telescopic cylinder (8) in a sliding manner, after being unfolded, the eighth connecting hole (89) is communicated with the fourth connecting hole (692), the sixth connecting hole (87) is communicated with the second connecting hole (68), and the fourth connecting hole (692) and the eighth connecting hole (89) are adjacent.

Further, when extreme weather occurs, the wind direction sensor (25) is started, the first power generation part (6) and the second power generation part (8) are folded and rotated to be folded, and the first power generation part and the second power generation part form an angle shape together with the inclined plate (37).

Furthermore, the shared power cabinet has two power supply modes, namely a power supply station power supply mode and a solar self-power supply mode, the power supply mode is selected according to the use frequency of the power supply cabinet, a time threshold value is set, and different power supply modes are selected through different threshold values.

The invention has the beneficial effects that:

1. the power supply system has two power supply modes, a time threshold interval with high utilization rate and a time threshold interval with low utilization rate are set through the use frequency of the power supply cabinet, the power supply system is in high utilization rate time and has high power consumption, the power supply station directly transmits power to carry out power supply and signal transmission on the shared charging cabinet, and the power supply system is in low utilization rate time and carries out power supply and signal transmission through the power stored in the storage battery by solar energy;

2. the power supply system has high flexibility, can adjust the irradiation angle according to the light angle, and improves the light utilization rate;

3. the power supply system has extreme weather resistance, detects the wind direction through the wind direction sensor, folds the power generation part into an angle shape, and reduces the wind resistance;

4. the power supply system has a self-dedusting function, reduces the influence of dust on the solar panel on illumination, and improves the illumination utilization rate.

Drawings

The invention will be further described with reference to the accompanying drawings.

FIG. 1 is a schematic diagram of the power supply system of the present invention;

FIG. 2 is a schematic diagram of a partial structure of a power supply system according to the present invention;

FIG. 3 is a schematic view of the fastener construction of the present invention;

FIG. 4 is an enlarged view of the structure of FIG. 3A according to the present invention;

FIG. 5 is a schematic diagram of a first signal transceiver according to the present invention;

FIG. 6 is a schematic diagram of a portion of a power supply system according to the present invention;

FIG. 7 is a schematic diagram of a portion of a power supply system according to the present invention;

FIG. 8 is a schematic view of a first power generation element of the present invention;

FIG. 9 is an enlarged view of the structure of FIG. 8 at B in accordance with the present invention;

FIG. 10 is a cross-sectional view of a first power generation element of the present invention;

FIG. 11 is a cross-sectional view of a first power generation element of the present invention;

FIG. 12 is a schematic view of a second power generation element of the present invention;

FIG. 13 is an enlarged view of FIG. 12 at C in accordance with the present invention;

FIG. 14 is a cross-sectional view of a second power generation element of the present invention;

fig. 15 is a cross-sectional view of a second power generation element of the present invention.

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.

Example 1

The utility model provides a 5G basic station power supply system based on sharing charges and trades electric cabinet, power supply system includes mounting 1, dust arrester and gas booster compressor, as shown in figure 1, fig. 2, it is equipped with and rotates piece 2 to rotate on the mounting 1, it is equipped with regulating part 3 to rotate on 2 to rotate, it is equipped with pneumatic cylinder 4 to rotate on 2 to rotate, be equipped with control 5 on the regulating part 3, it is equipped with symmetric distribution's first generating part 6 to rotate on the regulating part 3, be equipped with telescoping cylinder 7 on the first generating part 6, it is equipped with second generating part 8 to slide on the first generating part 6, the output shaft and the 8 fastening connection of second generating part of telescoping cylinder 7.

The fixing member 1 includes a fixing column 11, as shown in fig. 3 and 4, a first signal transceiver 12 is disposed on the fixing column 11, a second signal transceiver 13 is disposed on the fixing column 11, a third signal transceiver 14 is disposed on the fixing column 11, a fixing frame 15 is disposed on the fixing frame 11, a guide bar 16 is disposed on the fixing frame 15, first through holes 17 distributed in an array are disposed on the fixing frame 15, second through holes 18 distributed in an array are disposed on the fixing frame 15, a first driving member 19 is disposed on the fixing column 11, and the first signal transceiver 12, the second signal transceiver 13, and the third signal transceiver 14 are all slidably connected with the fixing frame 15.

The first signal transceiver 12 includes a signal transceiver 121, as shown in fig. 5, a first connecting rod 122 is rotatably disposed on the signal transceiver 121, a first sliding block 123 is rotatably disposed on the first connecting rod 122, the first sliding block 123 is slidably connected to the fixed frame 15, a first guiding slot 124 is disposed on the first sliding block 123, the first guiding slot 124 is slidably matched with the guiding rod 16, a third through hole 128 is disposed on the first sliding block 123, and the screw rod passes through the first through hole 17 and the third through hole 128 to fasten the fixed frame 15 and the first sliding block 123.

The signal transceiver 121 is rotatably provided with a second link 125, the second link 125 is slidably provided with a second slider 126, the second slider 126 is provided with a seventh through hole 1261, the second slider 126 is provided with an eighth through hole 1262, the signal transceiver 121 is rotatably provided with a third link 127, the third link 127 is provided with a fourth through hole 1271, a screw passes through the fourth through hole 1271 and the seventh through hole 1261 to tightly connect the second slider 126 and the third link 127, and the screw passes through the eighth through hole 1262 and the fifth through hole 1253 to tightly connect the second slider 126 and the second link 125.

The second connecting rod 125 includes a connecting rod body 1251, a limiting groove 1252 is provided on the connecting rod body 1251, fifth through holes 1253 distributed in an array are communicated in the limiting groove 1252, a fixing block 1254 is provided on the connecting rod body 1251, a second guide groove 1255 is provided on the fixing block 1254, a sixth through hole 1256 is provided on the fixing block 1254, the fixing block 1254 is slidably connected with the fixing frame 15, the second guide groove 1255 is slidably matched with the guide rod 16, and the screw rod passes through the second through hole 18 and the sixth through hole 1256 to fasten and connect the second connecting rod 125 and the fixing frame 15.

The first signal transceiver 12, the second signal transceiver 13 and the third signal transceiver 14 have the same structure and the same connection mode, and the difference is that the signal transceivers 121 on the first signal transceiver 12, the second signal transceiver 13 and the third signal transceiver 14 have different signal transceiving directions.

When the first signal transceiver 12, the second signal transceiver 13 and the third signal transceiver 14 are mounted, the first slider 123 and the second slider 126 are slid into the fixing frame 15 through the first guide groove 124 and the guide rod 16 in a sliding fit manner, after the direction of the signal transceiver 121 is adjusted to an optimum state, the third link 127 is rotated to adjust the second slider 126, the screw passes through the fourth through hole 1271 and the seventh through hole 1261 to fixedly connect the second slider 126 and the third link 127, and then the first slider 123 and the fixing block 1254 are fixed on the fixing frame 15.

The first driving member 19 includes a first fixing box 191 and a first gear 192, as shown in fig. 4, a rotating shaft 193 is disposed on the first gear 192, a motor is disposed in the first fixing box 191, and an output shaft of the motor passes through the first fixing box 191 and is tightly connected with the rotating shaft 193.

The rotating part 2 comprises a rotating column 21, as shown in fig. 6, a second gear 22 is arranged on the rotating column 21, a ninth through hole 23 is formed in the rotating column 21, the inner wall of the hydraulic cylinder 4 is rotatably connected with the inner wall of the ninth through hole 23, a rotating shaft hole 24 is formed in the rotating column 21, a wind direction sensor 25 is arranged on the rotating column 21, the rotating column 21 is rotatably connected with the fixed column 11, the second gear 22 is in meshing transmission with the first gear 192, the motor drives the second rotating part 2 to rotate through gear meshing transmission, the first power generating part 6 and the second power generating part 8 are driven to rotate through rotation of the second rotating part 2, and the angle is adjusted.

The adjusting part 3 comprises a support frame 31, as shown in fig. 7, the support frame 31 is provided with a rotating rod 32, the adjusting part 3 is rotatably connected with the rotating part 2 through the cooperation of the rotating rod 32 and the rotating shaft hole 24, a second fixing box 33 is arranged on the support frame 31, a motor is arranged in the second fixing box 33, a screw rod 34 is rotatably arranged on the support frame 31, an output shaft of the motor penetrates through the second fixing box 33 and is fixedly connected with the screw rod 34, a fixing plate 35 is arranged on the support frame 31, the screw rod 34 is rotatably connected with the fixing plate 35, a guide post 36 is arranged on the fixing plate 35, symmetrically distributed inclined plates 37 are arranged on the fixing plate 35, the inclined plates 37 are used for dividing wind power, wind power impact resistance is reduced, a photoelectric sensor 38 is arranged on the inclined plates 37, the photoelectric sensor 38 is used for detecting a sunlight irradiation angle, a tenth through hole 39 is arranged on the support frame 31, the tenth through hole 39 is in sliding fit with the rotating post 21, an output shaft of the hydraulic cylinder 4 is rotatably connected with the support frame 31, the photoelectric sensor 38 is used for detecting a sunlight irradiation angle, the output shaft of the hydraulic cylinder 4 pushes the support frame 31 to rotate, and further drive the fixing plate 35, the first power generating part 6 and the second power generating part 8 to rotate, so as to reduce the vertical conversion efficiency, and the heat loss.

The control member 5 comprises a control plate 51, as shown in fig. 7, the control plate 51 is rotatably provided with symmetrically distributed connecting plates 52, the control plate 51 is provided with a threaded hole 53, the screw rod 34 is in threaded fit with the threaded hole 53, and the control plate 51 is slidably connected with the guide post 36.

The first power generating element 6 includes a rotating frame 61, as shown in fig. 8, 9, 10, 11, a first solar panel 62 is disposed on the rotating frame 61, a support plate 63 is disposed on the rotating frame 61 and symmetrically disposed, a chute 64 is disposed on the support plate 63, first air holes 65 are disposed on the support plate 63 in an array manner, first dust suction holes 66 are disposed on the support plate 63 in an array manner, the first air holes 65 and the first dust suction holes 66 are alternately disposed, a first connection hole 67 is disposed in the support plate 63, the first connection hole 67 is communicated with the first air holes 65, a second connection hole 68 is communicated with the first air holes 65 at the end of the support plate 63, the first connection hole 67 is communicated with the second connection hole 68, one end of the second connection hole 68 is connected with a gas pressure booster through a connection pipe, the other end of the second connection hole 68 is communicated with the chute 64, the connection plate 52 is rotatably connected with the rotating frame 61, a third connection hole 691 is disposed on the support plate 63, the third connection hole 691 is communicated with the first connection hole 66, a fourth connection hole 692 is communicated with the first dust suction hole 66 at the end of the support plate 63, the fourth connection hole 692 is communicated with a dust collecting cylinder 692, the other end of the chute 692 is connected with the fourth connection pipe 692, and the telescopic cylinder 692 is connected with the chute 692.

The second power generating element 8 includes a sliding frame 81 and sliding plates 82 distributed symmetrically, as shown in fig. 12 to 15, a second solar panel 83 is disposed between the sliding plates 82 distributed symmetrically, second dust suction holes 84 are distributed in an array on the sliding plates 82, second air holes 85 distributed in an array are disposed on the sliding plates 82, a fifth connecting hole 86 is disposed on the sliding plates 82, the fifth connecting hole 86 is communicated with the second dust suction holes 84, a sixth connecting hole 87 is disposed on the sliding plates 82, the sixth connecting hole 87 is communicated with the fifth connecting hole 86, second air holes 85 distributed in an array are disposed on the sliding plates 82, a seventh connecting hole 88 is disposed on the sliding plates 82, the seventh connecting hole 88 is communicated with the second air holes 85, an eighth connecting hole 89 is communicated with the seventh connecting hole 88, the second power generating element 8 is slidably connected with the first power generating element 6 through the sliding plates 82 and the sliding grooves 64, an output shaft of the telescopic cylinder 7 is fixedly connected with the sliding frame 81, the output shaft of the telescopic cylinder 7 pushes the second power generating element 8 to move, the second solar panel 83 and the first solar panel 62 are opposite to each other, after being unfolded, the eighth connecting hole 89 is communicated with the fourth connecting hole 89, the fourth connecting hole 692 and the fourth connecting hole 692.

When the dust collector is used, the first signal transceiver 12, the second signal transceiver 13 and the third signal transceiver 14 are installed, the motor drives the screw rod 34 to rotate, the belt control plate 51 and the connecting plate 52 are driven to move through screw thread matching, the rotating frame 61 is further driven to rotate, the first solar panel 62 on the first power generation element 6 is driven to rotate and expand, the output shaft of the telescopic cylinder 7 drives the second power generation element 8 to move, the second solar panel 83 and the first solar panel 62 are relatively expanded, the eighth connecting hole 89 is communicated with the fourth connecting hole 692, the sixth connecting hole 87 is communicated with the second connecting hole 68, the hydraulic cylinder 4 drives the adjusting element 3 to rotate according to the light angle detected by the photoelectric sensor 38, the first solar panel 62 and the second solar panel 83 are further driven to rotate, sunlight is perpendicularly irradiated on the solar panels, heat loss is reduced, light conversion efficiency is improved, electric power is stored in the storage battery, when dust is collected, the gas booster blows out high-pressure gas from the first air hole 65 and the second air hole 85 to clean dust on the first solar panel 62 and the second solar panel 83, dust collector is started after dust is blown out, and dust is sucked into the first dust collecting hole 66 and the second dust collecting hole 84.

Example 2

When extreme weather occurs, the photoelectric sensor 38 stops working, the wind direction sensor 25 is started, the first power generation part 6 and the second power generation part 8 are folded and rotated to be folded, and form a pointed triangle together with the inclined plate 37, and according to the wind direction detected by the wind direction sensor 25, the motor drives the rotation part 2, the first power generation part 6 and the second power generation part 8 to rotate through gear meshing, so that the inclined plate 37 is pressed against the wind direction, and the wind resistance is reduced.

Example 3

The shared power cabinet is provided with two power supply modes which are a power supply station power supply mode and a solar self-power supply mode respectively, the power supply modes are selected according to the use frequency of the power supply cabinet, time threshold intervals of high use rate and low use rate are set, the power supply station is in the time of high use rate and has high power consumption, the power supply station directly transmits power to carry out power supply and signal transmission on the shared charging cabinet, the power supply station is in the time of low use rate, and power supply and signal transmission are carried out through the power stored in the storage battery through solar energy.

In the description herein, references to the description of "one embodiment," "an example," "a specific example," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the invention as claimed.

Claims (9)

1. The 5G base station power supply system based on the shared charging and converting cabinet is characterized by comprising a fixing piece (1), a dust collector and a gas supercharger, wherein the fixing piece (1) is rotatably provided with a rotating piece (2), the rotating piece (2) is rotatably provided with an adjusting piece (3), the rotating piece (2) is rotatably provided with a hydraulic cylinder (4), the adjusting piece (3) is provided with a control piece (5), the adjusting piece (3) is rotatably provided with first power generating pieces (6) which are symmetrically distributed, the first power generating pieces (6) are provided with telescopic cylinders (7), the first power generating pieces (6) are slidably provided with second power generating pieces (8), and output shafts of the telescopic cylinders (7) are fixedly connected with the second power generating pieces (8);

the fixing piece (1) comprises a fixing column (11), a first signal receiving and sending piece (12) is arranged on the fixing column (11), a second signal receiving and sending piece (13) is arranged on the fixing column (11), a third signal receiving and sending piece (14) is arranged on the fixing column (11), a fixing frame (15) is arranged on the fixing column (11), a guide rod (16) is arranged on the fixing frame (15), a first driving piece (19) is arranged on the fixing column (11), and the first signal receiving and sending piece (12), the second signal receiving and sending piece (13) and the third signal receiving and sending piece (14) are all in sliding connection with the fixing frame (15);

the first signal receiving and sending part (12) comprises a signal receiving and sending part (121), a first connecting rod (122) is rotatably arranged on the signal receiving and sending part (121), a first sliding block (123) is rotatably arranged on the first connecting rod (122), the first sliding block (123) is in sliding connection with the fixed frame (15), a first guide groove (124) is formed in the first sliding block (123), and the first guide groove (124) is in sliding fit with the guide rod (16);

a second connecting rod (125) is arranged on the signal transceiver (121) in a rotating mode, a second sliding block (126) is arranged on the second connecting rod (125) in a sliding mode, and a third connecting rod (127) is arranged on the signal transceiver (121) in a rotating mode;

second connecting rod (125) include connecting rod body (1251), are equipped with spacing groove (1252) on connecting rod body (1251), are equipped with fixed block (1254) on connecting rod body (1251), are equipped with second guide way (1255) on fixed block (1254), fixed block (1254) and mount (15) sliding connection, second guide way (1255) and guide bar (16) sliding fit.

2. The system of claim 1, wherein the first signal transceiver (12), the second signal transceiver (13) and the third signal transceiver (14) have the same structure and the same connection mode, and the difference is that the signal transceivers (121) on the first signal transceiver (12), the second signal transceiver (13) and the third signal transceiver (14) have different signal transceiving directions;

the first driving part (19) comprises a first fixing box (191) and a first gear (192), a rotating shaft (193) is arranged on the first gear (192), a motor is arranged in the first fixing box (191), and an output shaft of the motor penetrates through the first fixing box (191) to be fixedly connected with the rotating shaft (193).

3. The 5G base station power supply system based on the shared charging and converting cabinet is characterized in that the rotating part (2) comprises a rotating column (21), a second gear (22) is arranged on the rotating column (21), a ninth through hole (23) is formed in the rotating column (21), the hydraulic cylinder (4) is rotatably connected with the inner wall of the ninth through hole (23), a rotating shaft hole (24) is formed in the rotating column (21), a wind direction sensor (25) is arranged on the rotating column (21), the rotating column (21) is rotatably connected with the fixed column (11), and the second gear (22) is in meshing transmission with the first gear (192).

4. The 5G base station power supply system based on the shared charging and converting cabinet is characterized in that the adjusting part (3) comprises a support frame (31), the support frame (31) is provided with a rotating rod (32), the adjusting part (3) is in rotating connection with the rotating part (2) through the cooperation of the rotating rod (32) and a rotating shaft hole (24), a second fixing box (33) is arranged on the support frame (31), a motor is arranged in the second fixing box (33), a lead screw (34) is arranged on the support frame (31) in a rotating mode, an output shaft of the motor penetrates through the second fixing box (33) and is in fastening connection with the lead screw (34), a fixing plate (35) is arranged on the support frame (31), the lead screw (34) is in rotating connection with the fixing plate (35), a guide column (36) is arranged on the fixing plate (35), an inclined plate (37) is symmetrically distributed is arranged on the fixing plate (35), a photoelectric sensor (38) is arranged on the inclined plate (37), a tenth through hole (39) is formed in sliding connection with the rotating column (21), and an output shaft of a hydraulic cylinder (4) is connected with the support frame (31).

5. The 5G base station power supply system based on the shared charging and converting cabinet is characterized in that the control part (5) comprises a control board (51), the control board (51) is provided with connecting boards (52) which are symmetrically distributed in a rotating mode, the control board (51) is provided with a threaded hole (53), the screw rod (34) is in threaded fit with the threaded hole (53), and the control board (51) is in sliding connection with the guide column (36).

6. The 5G base station power supply system based on the shared charging and switching cabinet is characterized in that the first power generation part (6) comprises a rotating frame (61), a first solar panel (62) is arranged on the rotating frame (61), support plates (63) are symmetrically distributed on the rotating frame (61), sliding grooves (64) are formed in the support plates (63), first air holes (65) are distributed in an array mode on the support plates (63), first dust absorption holes (66) are distributed in an array mode on the support plates (63), the first air holes (65) are alternately distributed with the first dust absorption holes (66), first connection holes (67) are formed in the support plates (63), the first connection holes (67) are communicated with the first air holes (65), second connection holes (68) are communicated with the first air holes (65) at the end portions of the support plates (63), the first connection holes (67) are communicated with the second connection holes (68), one end portions of the second connection holes (68) are connected with a gas booster through connection pipes, the other ends of the second connection holes (64), the connection plates (52) are communicated with the rotating frame (61), the first connection holes (691) are communicated with the third connection holes (66), the fourth connection hole (692) is communicated with the third connection hole (691), one end of the fourth connection hole (692) is connected with the dust collector through a connection pipe, and the other end of the fourth connection hole (692) is communicated with the chute (64).

7. The 5G base station power supply system based on the shared charging and converting cabinet is characterized in that the second power generating element (8) comprises a sliding frame (81) and sliding plates (82) which are symmetrically distributed, a second solar panel (83) is arranged between the sliding plates (82) which are symmetrically distributed, second dust suction holes (84) are distributed in an array mode on the sliding plates (82), second air holes (85) are distributed in an array mode on the sliding plates (82), a fifth connecting hole (86) is arranged on the sliding plates (82), the fifth connecting hole (86) is communicated with the second dust suction holes (84), a sixth connecting hole (87) is communicated with the sliding plates (82), the sixth connecting hole (87) is communicated with the fifth connecting hole (86), a seventh connecting hole (88) is arranged on the sliding plates (82), the seventh connecting hole (88) is communicated with the second air hole (85), an eighth connecting hole (89) is communicated with the second air hole (85), the eighth connecting hole (89) is communicated with the seventh connecting hole (88), the second power generating element (8) is connected with the second power generating cylinder (7) through a sliding chute (82) and a sliding chute (64), the second power generating cylinder (8) is connected with the telescopic cylinder (7) in a sliding mode, and a telescopic cylinder (83) and a telescopic cylinder (8) is fastened, after being unfolded, the eighth connecting hole (89) is communicated with the fourth connecting hole (692), the sixth connecting hole (87) is communicated with the second connecting hole (68), and the fourth connecting hole (692) and the eighth connecting hole (89) are adjacent.

8. The 5G base station power supply system based on the shared charging and converting cabinet is characterized in that in extreme weather, the wind direction sensor (25) is started, and the first power generating element (6) and the second power generating element (8) are folded and rotated to be folded to form an angle shape together with the inclined plate (37).

9. The 5G base station power supply system based on the shared charging and exchanging cabinet as claimed in claim 1, wherein the shared electric cabinet has two power supply modes, namely a power supply station power supply mode and a solar self-power supply mode, the power supply mode is selected according to the use frequency of the power supply cabinet, a time threshold value is set, and different power supply modes are selected through different threshold values.

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