CN113175264A

CN113175264A - Signal enhancement tower based on photovoltaic technology

Info

Publication number: CN113175264A
Application number: CN202110371888.XA
Authority: CN
Inventors: 顾春兰
Original assignee: Yancheng Bianli Trading Co ltd
Current assignee: Yancheng Bianli Trading Co ltd
Priority date: 2021-04-07
Filing date: 2021-04-07
Publication date: 2021-07-27

Abstract

The invention discloses a signal enhancement tower based on a photovoltaic technology, which comprises a base, wherein a first motor is arranged on the upper side of the base, a first rotating shaft is arranged on the upper side of the first motor, two threaded shafts are rotatably connected to the upper side of the base, the threaded shafts are positioned on the front side of the first rotating shaft, and the threaded shafts are bilaterally symmetrical by taking the first rotating shaft as a center; the invention is suitable for scenic spots and can change positions according to the light and busy seasons of tourism, thereby reducing the waste of resources; the invention can be automatically installed in places with soft geology without any consumable; the photovoltaic panel can be charged in a photovoltaic mode, and the photovoltaic panel can be automatically contracted under the condition of bad weather, so that the service life of the photovoltaic panel is effectively prolonged.

Description

Signal enhancement tower based on photovoltaic technology

Technical Field

The invention relates to the field of signal emission, in particular to a signal enhancement tower based on a photovoltaic technology.

Background

Generally, only a few base stations are arranged in a natural scenic spot, which causes that the situation that important information is not received due to poor signals often occurs to passengers playing in the scenic spot, generally, a solution to the situation is to establish more base stations, and the like, but the travel has a weak and busy season, if the number of the base stations is determined according to the traffic of people in the busy season, the base stations lose use value in the weak season, and the cost performance of the method is low.

Disclosure of Invention

The object of the present invention is to provide a signal enhancement tower based on photovoltaic technology, which overcomes the above-mentioned drawbacks of the prior art.

The signal enhancement tower based on the photovoltaic technology comprises a base, wherein a first motor is arranged on the upper side of the base, a first rotating shaft is arranged on the upper side of the first motor, two threaded shafts are rotatably connected to the upper side of the base, the threaded shafts are positioned on the front side of the first rotating shaft and are bilaterally symmetrical around the first rotating shaft, the threaded shafts are connected with the first rotating shaft through synchronous belts, a mounting plate is arranged on the upper side of the base, two first cavities which are bilaterally symmetrical around the first rotating shaft are arranged in the mounting plate, the first cavity which is positioned on the left side is communicated in the front-back direction and is opened towards the left side, the first cavity which is positioned on the right side is opened towards the right side, and two threaded holes which pass through the first cavities upwards and penetrate through the mounting plate are arranged in the lower side face of the mounting plate, the two threaded shafts are respectively in threaded connection with the two threaded holes, the upper ends of the threaded shafts are located on the upper side of the mounting plate, a first photovoltaic panel is mounted on the upper side face of the mounting plate, a signal intensifier is fixedly arranged on the lower side face of the mounting plate, a power generation device capable of increasing light energy power generation power is arranged in each first cavity, a storage battery is arranged in the base, a second cylindrical cavity is arranged in the base, a first flow passage penetrating downwards into the second cavity is formed in the upper side face of the base, an air pump is fixedly arranged on the upper side face of the base and connected with the first flow passage, a plurality of air-tight holes penetrating downwards the base are arranged in the bottom wall of the second cavity, the air-tight holes are distributed at equal angles by taking the circle center of the upper side face of the second cavity as the center, and a fixing device capable of fixing the base on the ground is arranged in each air-tight hole, the base of the lower side of the second cavity is internally provided with a third cavity with a downward opening, the third cavity is internally provided with an airtight sliding block in up-down sliding connection, the airtight sliding block is internally provided with a driving device, the driving device can enable the base to move when the fixing device takes effect, and the annular surface of the third cavity of the lower side of the third cavity is fixedly provided with a first limiting block.

Optionally, power generation facility is including locating backup pad in the cavity, be equipped with a through-hole that link up from top to bottom in the backup pad, the axis of a through-hole with the axis collineation of screw hole and the diameter of a through-hole is greater than the diameter of screw hole, a through-hole outer loop be equipped with the circular slot in the cavity downside and set firmly on the backup pad downside extend to the spacing ring in the circular slot, be equipped with a spout in the screw shaft collar face and set firmly on the through-hole ring face extend to a slider in the spout, the side is equipped with No. two photovoltaic boards in the backup pad.

Optionally, an air pressure sensor is arranged on the top wall of the third cavity, and an air pressure sensor is arranged on the top wall of the second cavity.

Optionally, the fixing device comprises a second sliding block which is connected with the airtight hole in an up-and-down sliding manner, the lower side surface of the second sliding block is conical, a second runner which penetrates through the second sliding block upwards is arranged in the second sliding block, a second sliding chute which is communicated with the second runner and runs through the second sliding chute from left to right is arranged in the second sliding block, the second sliding chute is internally connected with a third sliding block which extends outwards to the outside of the second sliding chute in an up-and-down sliding manner, an extension rod which extends to the upper side of the second sliding chute is arranged on the upper side surface of the third sliding block, a blocking block is fixedly arranged at the upper end of the extension rod and can block the second sliding chute, a first airtight block is fixedly arranged on the ring surface of the second sliding block, a second limiting block is fixedly arranged on the ring surface of the airtight hole, two third sliding chutes which are symmetrical left and right and open outwards are arranged in the second sliding block, sliding connection has the butt piece in No. three spouts, be equipped with No. two airtight pieces on the butt piece anchor ring, No. three stoppers have set firmly on the No. three spout anchor ring, communicate through No. three runners on the anchor ring of No. two runner downside in No. three spouts, be equipped with in No. two sliders and attract an electro-magnet of butt piece, the side sets firmly on No. two cavitys can attract No. two electro-magnets of No. two sliders.

Optionally, the driving device includes a pneumatic motor disposed in the lower side face of the airtight slider, a fourth flow channel communicated with the pneumatic motor to the left is disposed in the upper side face of the airtight slider after extending downwards, a first ball valve is disposed in the fourth flow channel, a second rotating shaft is mounted on the lower side face of the pneumatic motor, a first bevel gear is mounted at the end of the second rotating shaft, a mounting plate is fixedly disposed on the lower side face of the airtight slider, a third rotating shaft is rotatably connected in the left side face of the mounting plate, a second bevel gear meshed with the first bevel gear is mounted at the left end of the third rotating shaft, two driving wheels are mounted on the third rotating shaft, a fifth flow channel extending downwards after extending backwards is disposed in the rear side face of the first flow channel, the end of the fifth flow channel penetrates forwards to the rear side face of the third cavity, and a second ball valve is disposed in the fifth flow channel, be equipped with No. two motors in the airtight slider and No. four axis of rotation are installed to No. two motor downside faces, airtight slider downside internal rotation is connected with the carousel, the carousel can by No. four axis of rotation drive the rotation, two supporting shoes are installed to the carousel downside and rotate between the supporting shoe and be connected with No. five axis of rotation, install from the driving wheel in No. five axis of rotation.

Optionally, a stress block is fixedly arranged on the lower side surface of the airtight sliding block, and the third rotating shaft penetrates through and is rotatably connected to the stress block.

Optionally, a third ball valve is arranged in the first flow channel, and the third ball valve is located on the lower side of the fifth flow channel.

Optionally, the side is equipped with air sensor and rainfall sensor on photovoltaic board No. one.

Optionally, be equipped with in No. three cavity roof and upwards link up to No. two gas vents in the cavity, be equipped with No. four ball valves in the gas vent, be equipped with in No. two cavity roof and upwards link up No. two gas vents of base, be equipped with No. five ball valves in No. two gas vents.

The invention has the beneficial effects that: the invention can enhance the wireless signal;

the invention is suitable for scenic spots and can change positions according to the light and busy seasons of tourism, thereby reducing the waste of resources;

the invention can be automatically installed in places with soft geology without any consumable;

the photovoltaic panel can be charged in a photovoltaic mode, and the photovoltaic panel can be automatically contracted under the condition of bad weather, so that the service life of the photovoltaic panel is effectively prolonged.

Drawings

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention; it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and all other embodiments obtained by those skilled in the art without any inventive work are within the scope of the present invention.

FIG. 1 is a schematic diagram of a signal enhancement tower of the present invention based on photovoltaic technology;

FIG. 2 is a schematic diagram of the structure at the power plant of FIG. 1;

FIG. 3 is a schematic view of the structure at A-A in FIG. 1;

FIG. 4 is a schematic view of the arrangement of FIG. 1 at the fixture;

FIG. 5 is a schematic view of the vent of FIG. 1;

FIG. 6 is a schematic view of the structure of the air pump of FIG. 1;

FIG. 7 is a schematic view of the structure of the driving device of FIG. 1;

fig. 8 is a schematic bottom view of the turntable of the present invention.

Detailed Description

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "top/bottom", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referred device or assembly must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

Referring to fig. 1 to 8, the signal enhancement tower based on the photovoltaic technology according to the present invention includes a base 11, a first motor 12 is installed on an upper side of the base 11, a first rotating shaft 13 is installed on an upper side of the first motor 12, two threaded shafts 14 are rotatably connected to an upper side of the base 11, the threaded shafts 14 are located in front of the first rotating shaft 13 and are bilaterally symmetrical about the first rotating shaft 13, the threaded shafts 14 are connected to the first rotating shaft 13 through a synchronous belt 15, a mounting plate 16 is disposed on an upper side of the base 11, two first cavities 17 are disposed in the mounting plate 16 and are bilaterally symmetrical about the first rotating shaft 13, the first cavities 17 are through from front to back and are left-opened, the first cavities 17 on a left side are opened to the left, the first cavities 17 on a right side are opened to the right, be equipped with in the mounting panel 16 downside upwards respectively through two cavity 17 and run through two screw hole 18 of mounting panel 16, two screw shaft 14 respectively with two screw hole 18 threaded connection and the upper end of screw shaft 14 is located the upside of mounting panel 16, photovoltaic board 19 is installed and the downside of mounting panel 16 has set firmly signal intensifier 20 to the side of going up of mounting panel 16, every all be equipped with a power generation facility 101 that can increase light energy power generation in cavity 17, be equipped with battery 21 in the base 11 and be equipped with cylindric cavity 22 No. two in the base 11, be equipped with the runner 34 that link up downwards in cavity 22 No. two in the side of going up of base 11, the side of going up of base 11 has set firmly air pump 33 and air pump 33 with runner 34 No. one is connected, a plurality of airtight holes 23 which penetrate through the base 11 downwards are arranged in the bottom wall of the second cavity 22, the airtight holes 23 are distributed at equal angles by taking the circle center of the upper side surface of the second cavity 22 as the center, a fixing device 102 capable of fixing the base 11 on the ground is arranged in each airtight hole 23, a third cavity 24 with a downward opening is arranged in the base 11 on the lower side of the second cavity 22, an airtight sliding block 25 is connected in the third cavity 24 in a vertical sliding mode, a driving device 103 is arranged in the airtight sliding block 25, the driving device 103 can enable the base 11 to move when the fixing device 102 is effective, and a first limiting block 35 is fixedly arranged on the ring surface of the third cavity 24 on the lower side of the third cavity 24.

Preferably, the power generation device 101 includes a support plate 26 disposed in the first cavity 17, a first through hole 27 penetrating up and down is disposed in the support plate 26, an axis of the first through hole 27 is collinear with an axis of the threaded hole 18, and a diameter of the first through hole 27 is larger than a diameter of the threaded hole 18, a circular groove 31 is disposed in a lower side surface of the first cavity 17 of an outer ring of the first through hole 27, a limit ring 32 extending into the circular groove 31 is fixedly disposed on a lower side surface of the support plate 26, a first sliding groove 28 is disposed in a ring surface of the threaded shaft 14, a first sliding block 29 extending into the first sliding groove 28 is fixedly disposed on a ring surface of the first through hole 27, a second photovoltaic plate 30 is disposed on an upper side surface of the support plate 26, when the threaded shaft 14 rotates, the mounting plate 16 connected with the threaded shaft in a threaded manner is driven to move up or down, and the rotation of the threaded shaft 14 drives the first sliding block 29 to rotate the support plate 26, rotation of the support plate 26 causes the second photovoltaic panel 30 thereon to enter or exit the first cavity 17.

Preferably, a first air pressure sensor 67 is arranged on the top wall of the third cavity 24, and a second air pressure sensor 68 is arranged on the top wall of the second cavity 22.

Preferably, the fixing device 102 includes a second sliding block 36 slidably connected to the airtight hole 23 from top to bottom, the lower side surface of the second sliding block 36 is tapered, a second sliding channel 37 upwardly penetrating through the second sliding block 36 is provided in the second sliding block 36, a second sliding slot 38 penetrating from left to right and communicating with the second sliding channel 37 is provided in the second sliding block 36, a third sliding block 39 extending outward from the second sliding slot 38 is slidably connected to the second sliding slot 38 from top to bottom, an extension rod 40 extending to the upper side of the second sliding channel 37 is provided on the upper side surface of the third sliding block 39, a blocking block 41 is fixedly provided on the upper end of the extension rod 40, the blocking block 41 can block the second sliding channel 37, a first airtight block 42 is fixedly provided on the annular surface of the second sliding block 36, the first airtight block 42 is provided on the upper side of the second sliding slot 38, a second limiting block 43 is fixedly provided on the annular surface of the airtight hole 23, two bilaterally symmetrical third sliding grooves 44 with outward openings are arranged in the second sliding block 36, a butting block 45 is connected in the third sliding groove 44 in a sliding mode, a second airtight block 46 is arranged on the ring surface of the butting block 45, a third limiting block 48 is fixedly arranged on the ring surface of the third sliding groove 44, the ring surface of the lower side of the second flow channel 37 is communicated with the third sliding groove 44 through a third flow channel 47, a first electromagnet 49 capable of attracting the butting block 45 is arranged in the second sliding block 36, a second electromagnet 71 capable of attracting the second sliding block 36 is fixedly arranged on the upper side surface of the second cavity 22, when gas enters the second cavity 22, the second sliding block 36 is pushed to move downwards, at the moment, the blocking block 41 blocks the second sliding block 36, the lower side surface of the third sliding block 39 abuts against the lower side surface of the second sliding groove 38, and the third sliding block 39 moves upwards when the third sliding block 39 abuts against the upper side surface of the second limiting block 43 along with the movement of the second sliding block 36, at this moment, the third sliding block 39 drives the extension rod 40 to enable the blocking block 41 to move upwards, when the upper side surface of the third sliding block 39 abuts against the upper side surface of the second sliding groove 38 to enable the second sliding block 36 to stop moving, the second sliding block 36 is deeply buried underground at this moment, in the process, gas can sequentially pass through the second flow channel 37 and the third flow channel 47 to enter the third sliding groove 44, and the gas entering the third sliding groove 44 can enable the abutting block 45 to move outwards and be embedded in underground soil.

Preferably, the driving device 103 includes an air motor 50 disposed in the lower side surface of the airtight slider 25, a fourth flow passage 51 extending downward and communicating with the air motor 50 to the left is disposed in the upper side surface of the airtight slider 25, the left end of the fourth flow passage 51 penetrates the airtight slider 25 downward and a first ball valve 52 is disposed in the fourth flow passage 51, a second rotating shaft 53 is mounted on the lower side surface of the air motor 50 and a first bevel gear 54 is mounted at the end of the second rotating shaft 53, a mounting plate 55 is fixedly disposed on the lower side surface of the airtight slider 25, a third rotating shaft 56 is rotatably connected in the left side surface of the mounting plate 55 and a second bevel gear 57 engaged with the first bevel gear 54 is mounted at the left end of the third rotating shaft 56, two driving wheels 58 are mounted on the third rotating shaft 56, a fifth flow passage 59 extending rearward and extending downward is disposed in the rear side surface of the first flow passage 34, the tail end of the fifth flow passage 59 penetrates forward to the rear side face of the third cavity 24, a second ball valve is arranged in the fifth flow passage 59, a second motor is arranged in the airtight sliding block 25, a fourth rotating shaft is arranged on the lower side face of the second motor, a rotating disc 63 is connected in the lower side face of the airtight sliding block 25 in a rotating mode, the rotating disc 63 can be driven by the fourth rotating shaft to rotate, two supporting blocks 64 are arranged on the lower side face of the rotating disc 63, a fifth rotating shaft 65 is connected between the supporting blocks 64 in a rotating mode, a driven wheel 66 is arranged on the fifth rotating shaft 65, when the third cavity 24 is filled with gas, the airtight sliding block 25 slides downwards until the lower side face of the airtight sliding block 25 abuts against the upper side face of the first limiting block 35, at the moment, the driving wheel 58 and the driven wheel 66 support the base 11, and at the moment, the lower side face of the base 11 is separated from the ground, and when the base 11 needs to move, the first ball valve 52 is opened, at this moment, high-pressure gas in the third cavity 24 is discharged after passing through the fourth flow passage 51, the gas passing through the fourth flow passage 51 drives the second rotating shaft 53 to rotate through the pneumatic motor 50, the third rotating shaft 56 is driven to rotate through the first bevel gear 54 and the second bevel gear 57 which are meshed with each other when the second rotating shaft 53 rotates, the driving wheel 58 is driven to move, a worker needs to electrify the second motor when needing to turn, the turntable 63 is driven to rotate through driving the fourth rotating shaft when the second motor is electrified, and the driven wheel 66 rotates and changes the moving direction of the base 11 when the turntable 63 rotates.

Preferably, a stress block 70 is fixedly arranged on the lower side surface of the airtight sliding block 25, the third rotating shaft 56 penetrates through and is rotatably connected to the stress block 70, and the stress block 70 can reduce the abrasion of the first bevel gear 54 and reduce the fault of the connection position of the third rotating shaft 56 and the mounting plate 55.

Preferably, a third ball valve 62 is arranged in the first flow passage 34, and the third ball valve is positioned at the lower side of the fifth flow passage 59.

Preferably, an air volume sensor 60 and a rainfall sensor 61 are arranged on the upper side surface of the first photovoltaic panel 19.

Preferably, a first exhaust port 81 which penetrates through the second cavity 22 upwards is formed in the top wall of the third cavity 24, a fourth ball valve 82 is arranged in the first exhaust port 81, a second exhaust port 83 which penetrates through the base 11 upwards is formed in the top wall of the second cavity 22, and a fifth ball valve 84 is arranged in the second exhaust port 83.

In the initial state, the fixture 102 is in effect and the second slider 36 is located underground, and the drive pulley 58 and the driven pulley 66 are located in the third cavity 24, the mounting plate 16 is located at the upper limit of the threads of the threaded shaft 14, and most of the area of the second photovoltaic panel 30 is located outside the first cavity 17.

When the outside weather is strong wind or strong rain, the wind sensor 60 or the rain sensor 61 controls the first motor 12 to be electrified for a certain time, the first motor 12 drives the synchronous belt 15 to move to enable the threaded shaft 14 to rotate when being electrified, the threaded shaft 14 enables the supporting plate 26 to rotate when being rotated, the first motor 12 is electrified for a certain time to enable the supporting plate 26 to be positioned in the first cavity 17, then the first motor 12 is powered off, at the moment, the second photovoltaic panel 30 is protected, and in the process, the mounting plate 16 moves downwards for a small distance, when weather is good, the first motor 12 is powered on and drives the first rotating shaft 13 to rotate reversely, the first rotating shaft 13 drives the threaded shaft 14 to rotate reversely, the first motor 12 is powered off when the mounting plate 16 moves to the upper limit of the threads of the threaded shaft 14 again after a certain time, and most area of the second photovoltaic plate 30 is located outside the first cavity 17 again and photovoltaic power generation is carried out.

When the base 11 needs to move, the first motor 12 is powered on and the threaded shaft 14 rotates, the mounting plate 16 moves downwards, the second motor 12 is powered off when the mounting plate 16 moves to the lower limit of the threads of the threaded shaft 14, the gravity center of the base 11 is lowered, the fifth ball valve 84 is opened and the first electromagnet 49 is powered on, the first electromagnet 49 is powered on to attract the abutting block 45 and enable the abutting block 45 to move into the third sliding groove 44, the second electromagnet 71 is powered on, the second slider 36 is attracted to move upwards when the second electromagnet 71 is powered on until the upper side surface of the second slider 36 abuts against the lower side surface of the second electromagnet 71, the fifth ball valve 84 is closed, the third ball valve 62 is closed and the second ball valve is opened, the air pump 33 is powered on, air enters the third cavity 24 through the fifth flow passage 59 when the air pump 33 is powered on, the air-tight slider 25 is pushed to move downwards until the lower side surface of the air-tight slider 25 abuts against the upper side surface of the limiting block 35, then, when the air pressure in the airtight sliding block 25 reaches the threshold value of the first air pressure sensor 67, the air pump 33 is powered off, and then if the first ball valve 52 is opened to enable the driving wheel 58 to rotate, the air pressure in the third cavity 24 is reduced, and when the air pressure in the third cavity 24 is reduced, the air pump 33 is controlled by the first air pressure sensor 67 to be powered on again, and at the moment, the base 11 can move.

When the base 11 moves to a predetermined place and needs to be fixed, the fourth ball valve 82 and the third ball valve 62 are opened, the fifth ball valve 84 and the second ball valve are closed, at this time, the airtight sliding block 25 slides upwards due to gravity, the lower side surface of the base abuts against the ground, then the air pump 33 is powered on, the fixing device 102 is enabled, when the air pressure in the second cavity 22 reaches the threshold value of the second air pressure sensor 68, the air pump 33 is powered off, and at this time, the base 11 is fixed.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims

1. A signal enhancement tower based on photovoltaic technology, includes the base, its characterized in that: a motor is installed on the upper side of the base, a first rotating shaft is installed on the upper side of the motor, the upper side of the base is connected with two threaded shafts in a rotating mode, the threaded shafts are located on the front side of the first rotating shaft and are in bilateral symmetry with the first rotating shaft as a center, the threaded shafts are connected with the first rotating shaft through synchronous belts, a mounting plate is arranged on the upper side of the base, two first cavities which are in bilateral symmetry with the first rotating shaft as a center are arranged in the mounting plate, the first cavities are communicated in the front and back direction and are located on the left side, the first cavities are opened leftwards, the first cavities are opened rightwards, two threaded holes which are upwards communicated with the first cavities and are communicated with the mounting plate are formed in the lower side surface of the mounting plate, the two threaded shafts are in threaded connection with the two threaded holes respectively, and the upper ends of the threaded shafts are located on the upper side of the mounting plate, the photovoltaic panel is arranged on the upper side surface of the mounting plate, the signal intensifier is fixedly arranged on the lower side surface of the mounting plate, a power generation device capable of increasing light energy power generation power is arranged in each cavity, a storage battery is arranged in the base, a cylindrical second cavity is arranged in the base, a first flow passage penetrating into the second cavity downwards is arranged in the upper side surface of the base, an air pump is fixedly arranged on the upper side surface of the base and connected with the first flow passage, a plurality of airtight holes penetrating through the base downwards are arranged in the bottom wall of the second cavity, the airtight holes are distributed at equal angles by taking the circle center of the upper side surface of the second cavity as the center, a fixing device capable of fixing the base on the ground is arranged in each airtight hole, and a third cavity with a downward opening is arranged in the base on the lower side of the second cavity, an airtight sliding block is connected in the third cavity in a vertical sliding mode, a driving device is arranged in the airtight sliding block, the driving device can enable the base to move when the fixing device takes effect, and a first limiting block is fixedly arranged on the ring surface of the third cavity on the lower side of the third cavity.

2. The signal enhancement tower based on photovoltaic technology of claim 1, wherein: generating device is including locating backup pad in the cavity, be equipped with a through-hole that link up from top to bottom in the backup pad, the axis of a through-hole with the axis collineation of screw hole and the diameter of a through-hole is greater than the diameter of screw hole, a through-hole outer loop be equipped with the circular slot in the cavity downside and set firmly on the backup pad downside and extend to spacing ring in the circular slot, be equipped with a spout in the screw thread axle collar facial and set firmly on the through-hole ring and extend to a slider in the spout, the side is equipped with the photovoltaic board No. two in the backup pad.

3. The signal enhancement tower based on photovoltaic technology of claim 1, wherein: and a first air pressure sensor is arranged on the top wall of the third cavity, and a second air pressure sensor is arranged on the top wall of the second cavity.

4. The signal enhancement tower based on photovoltaic technology of claim 1, wherein: the fixing device comprises a second sliding block which is connected in the airtight hole in an up-and-down sliding manner, the lower side surface of the second sliding block is conical, a second runner which penetrates through the second sliding block upwards is arranged in the second sliding block, a second sliding chute which is communicated with the second runner and runs through the second sliding chute from left to right is arranged in the second sliding block, a third sliding block which extends outwards to the outside of the second sliding chute is connected in the second sliding chute in an up-and-down sliding manner, an extension rod which extends to the upper side of the second sliding chute is arranged on the upper side surface of the third sliding block, a blocking block is fixedly arranged at the upper end of the extension rod and can block the second sliding chute, a first airtight block is fixedly arranged on the ring surface of the second sliding block, a first airtight block is positioned on the upper side of the second sliding chute, a second limiting block is fixedly arranged on the ring surface of the airtight hole, and two third sliding chutes which are symmetrical from left to right and are provided with outwards openings are arranged in the second sliding block, sliding connection has the butt piece in No. three spouts, be equipped with No. two airtight pieces on the butt piece anchor ring, No. three stoppers have set firmly on the No. three spout anchor ring, communicate through No. three runners on the anchor ring of No. two runner downside in No. three spouts, be equipped with in No. two sliders and attract an electro-magnet of butt piece, the side sets firmly on No. two cavitys can attract No. two electro-magnets of No. two sliders.

5. The signal enhancement tower based on photovoltaic technology of claim 1, wherein: the driving device comprises a pneumatic motor arranged in the lower side face of the airtight sliding block, a fourth flow channel communicated with the pneumatic motor to the left after extending downwards is arranged in the upper side face of the airtight sliding block, the left end of the fourth flow channel penetrates through the airtight sliding block downwards, a ball valve is arranged in the fourth flow channel, a second rotating shaft is arranged on the lower side face of the pneumatic motor, a first bevel gear is arranged at the tail end of the second rotating shaft, a mounting plate is fixedly arranged on the lower side face of the airtight sliding block, a third rotating shaft is rotatably connected in the left side face of the mounting plate, a second bevel gear meshed with the first bevel gear is arranged at the left end of the third rotating shaft, two driving wheels are arranged on the third rotating shaft, a fifth flow channel extending downwards after extending backwards is arranged in the rear side face of the first flow channel, the tail end of the fifth flow channel penetrates forwards to the rear side face of the third cavity, and a second ball valve is arranged in the fifth flow channel, be equipped with No. two motors in the airtight slider and No. four axis of rotation are installed to No. two motor downside faces, airtight slider downside internal rotation is connected with the carousel, the carousel can by No. four axis of rotation drive the rotation, two supporting shoes are installed to the carousel downside and rotate between the supporting shoe and be connected with No. five axis of rotation, install from the driving wheel in No. five axis of rotation.

6. The signal enhancement tower of claim 5, wherein: and a stress block is fixedly arranged on the lower side surface of the airtight sliding block, and the third rotating shaft penetrates through and is rotatably connected with the stress block.

7. The signal enhancement tower of claim 5, wherein: a third ball valve is arranged in the first runner and is positioned on the lower side of the fifth runner.

8. The signal enhancement tower based on photovoltaic technology of claim 1, wherein: the side is equipped with air sensor and rainfall sensor on photovoltaic board.

9. The signal enhancement tower of claim 5, wherein: be equipped with in No. three cavity roof and upwards link up to No. two gas vents in the cavity, be equipped with No. four ball valves in the gas vent, be equipped with in No. two cavity roof and upwards link up No. two gas vents of base, be equipped with No. five ball valves in the gas vent No. two.