CN114941465A

CN114941465A - Multifunctional platform for transmission line tower

Info

Publication number: CN114941465A
Application number: CN202210401731.1A
Authority: CN
Inventors: 周哲恒; 吴伟强; 章道阳; 王成; 向新宇; 毛元媛; 张斌; 李璠; 王晓东; 宋超波; 于旨坚; 邬韦华; 杨珂; 杨俊�; 茅泽乾
Original assignee: Hangzhou Power Supply Co of State Grid Zhejiang Electric Power Co Ltd
Current assignee: Hangzhou Power Supply Co of State Grid Zhejiang Electric Power Co Ltd
Priority date: 2022-04-18
Filing date: 2022-04-18
Publication date: 2022-08-26
Anticipated expiration: 2042-04-18
Also published as: CN114941465B

Abstract

The invention discloses a multifunctional platform for a power transmission line tower, which comprises a solar module and an information collection and communication module; the information collection and communication module is connected with the solar module; the multifunctional platform further comprises a supporting platform, the supporting platform is fixedly connected with the tower, and the solar module and the information collecting and communication module are arranged on the supporting platform. Compared with the prior art, the multifunctional platform for the transmission line tower provided by the invention can reduce operation and maintenance cost, and is time-saving and labor-saving in mounting the terminal device.

Description

Multifunctional platform for transmission line tower

Technical Field

The invention relates to the technical field of remote power systems, in particular to a multifunctional platform for a power transmission line tower.

Background

The power transmission line serving as the power transmission link has the characteristics of large dispersity, long distance, complex terrain and the like. In order to improve the operation and maintenance efficiency and realize lean management of the production and operation of the power transmission line, the terminal devices for on-line monitoring of the power transmission line are more and more widely applied. The terminal device comprises a video monitoring device, a microclimate monitoring device, a mountain fire alarm device, an external damage prevention monitoring device, a tower inclination device and the like. In the prior art, terminal devices are generally equipped with a separate solar module for power supply. When the terminal device is installed on the tower, the independent solar module needs to be installed for the installed terminal device every time, and time and labor are wasted. In addition, in order to transmit the data monitored by the terminal device to the background, when the terminal device is installed on the tower, an independent communication card needs to be installed for the installed terminal device every time, and the operation and maintenance cost is greatly improved.

Disclosure of Invention

The invention provides a time-saving and labor-saving multifunctional platform for a power transmission line tower, which aims to overcome the defects of time and labor waste and high cost of terminal device installation in the prior art.

In order to achieve the purpose, the invention adopts the following technical scheme:

a multifunctional platform of a power transmission line tower comprises a solar module and an information collecting and communicating module; the information collection and communication module is connected with the solar module; the multifunctional platform further comprises a supporting platform, the supporting platform is fixedly connected with the tower, and the solar module and the information collecting and communication module are arranged on the supporting platform.

Furthermore, the tower comprises a plurality of tower main materials, one end of each tower main material is fixedly connected with the ground, the other end of each tower main material extends upwards, the support table is arranged between the tower main materials, and the outer edge of the support table is fixedly connected with the tower main materials.

Furthermore, the supporting table comprises a plurality of supporting rods, the supporting rods are fixedly connected with one another, the supporting rods are fixedly connected with the main tower material, and a passing space for workers to pass through is formed between the supporting rods.

Furthermore, a bird-guiding nest is arranged on the supporting platform.

Furthermore, the supporting table further comprises an accommodating frame used for accommodating the solar module, the supporting rod is arranged on the outer side of the accommodating frame and fixedly connected with the accommodating frame, one side of the solar module is rotatably connected with one side of the accommodating frame, and a driving device used for driving the solar module to rotate is arranged on the supporting table.

Further, solar module includes the electricity generation portion, rotate head and supporting part, the electricity generation portion sets up in one side of supporting part, the supporting part is including rotating the limit, go up and down the limit, first support limit and second support limit set up rotate between limit and the limit that goes up and down, rotate the head and rotate the limit and rotate the connection, rotate the head and hold one side of frame and rotate the connection, first support limit and second support limit all are provided with the strutting arrangement who is used for and hold the upside butt of the edge of frame.

Further, the supporting device is disposed on a side of the supporting portion away from the charging portion.

Furthermore, one side of the supporting part far away from the power generation part is fixedly connected with a plurality of reinforcing ribs.

Furthermore, the driving device comprises a first driving rod, a second driving rod and a driving rotating mechanism, one end of the first driving rod is rotatably connected with the lifting edge, the other end of the first driving rod is rotatably connected with the second driving rod, the second driving rod is connected with the driving rotating mechanism, and the driving rotating mechanism is arranged on the supporting table.

Further, the drive rotary mechanism includes the first cylinder body with a supporting table fixed connection, sliding connection is at the first piston in the first cylinder body, the first piston rod with first piston connection, the air pump with first cylinder body connection, air pump and solar module connect, the one end that first piston was kept away from to first piston rod is provided with the spout, the one end setting of second actuating lever is in the spout, second actuating lever and spout sliding connection just rotate with the spout to be connected, the inboard of spout is provided with and is spiral helicine guide way, second actuating lever fixedly connected with guide block, the guide block sets up in the guide way, be provided with first spring in the spout, the one end and the second actuating lever of first spring are connected, the other end and the tank bottom of spout of first spring are connected.

Furthermore, the supporting device comprises a second cylinder fixedly connected with the supporting part, a second piston slidably connected in the second cylinder, a second piston rod connected with the second piston, and a second spring arranged in the second cylinder, the second piston rod comprises a first end and a second end, the first end is connected with the second piston, the second end of the supporting device on the first supporting edge extends to one side far away from the second supporting edge, the second end of the supporting device on the second supporting edge extends to one side far away from the first supporting edge, a first cavity is arranged in the first cylinder, the first cavity is arranged at one side of the first piston far away from the first piston rod, a second cavity is arranged in the second cylinder, the second cavity is arranged at one side of the first piston close to the first piston rod, the air pump is communicated with the first cavity, the first piston is provided with a first air passage, the first piston rod is provided with a second air passage, one end of the first air passage is communicated with the first cavity, the other end of the first air passage is communicated with the second air passage, the second air passage is communicated with the chute, the second driving rod is provided with a third air passage, the third air passage is communicated with the chute, the first piston rod is provided with a fourth air passage, and the fourth air passage is communicated with the second cavity; when the guide block is positioned at one end of the guide groove far away from the first piston, the third air passage is communicated with the fourth air passage.

Compared with the prior art, the multifunctional platform for the transmission line tower provided by the invention can reduce operation and maintenance cost, and is time-saving and labor-saving in mounting the terminal device.

Drawings

Fig. 1 is a side view of an embodiment of the present application.

Fig. 2 is a cross-sectional view a-a of fig. 1 of an embodiment of the present application.

Fig. 3 is a cross-sectional view of fig. 2 along a reference plane of an embodiment of the present application.

Fig. 4 is a schematic view of a solar module of an embodiment of the present application rotated into a receiving frame.

Fig. 5 is a schematic view of a solar module according to an embodiment of the present application after being rotated 180 degrees.

Fig. 6 is another schematic view of a solar module according to an embodiment of the present application after being rotated 180 degrees.

Fig. 7 is an enlarged view at B of fig. 3 of an embodiment of the present application.

Fig. 8 is an enlarged view at C of fig. 5 of an embodiment of the present application.

Fig. 9 is an enlarged view at D of fig. 6 of an embodiment of the present application.

Detailed Description

The technical scheme of the invention is further specifically described by the following embodiments and the accompanying drawings.

Referring to fig. 1 and 2, a multifunctional platform 100 for a power transmission line tower comprises a solar module 11 and an information collecting and communicating module 12. The solar module 11 may be configured as a solar panel and the information collecting and communicating module 12 may be configured as a communication card. The information collection and communication module 12 is connected to the solar module 11. Specifically, the solar module 11 is connected to a battery 13 so as to charge the battery 13 by using solar energy, and the battery 13 is connected to the information collecting and communicating module 12 so as to supply power to the information collecting and communicating module 12, thereby operating the information collecting and communicating module 12. The multi-function platform 100 further comprises a support platform 14, the support platform 14 extending substantially in a horizontal plane and being fixedly connected to the tower 200, the solar module 11 and the information collecting and communicating module 12 being arranged on the support platform 14. Specifically, the solar module 11 and the information collecting and communicating module 12 are both fixedly connected to the support platform 14 by bolts. After an operator installs a terminal device (not shown in the figure) on the tower 200, the solar module 11 is connected with the terminal device for supplying power to the terminal device, and the information collecting and communicating module 12 is connected with the terminal device for transmitting data of the terminal device to the background. The installation of the separate solar module 11 and the information collecting and communicating module 12 for the installed terminal device is not required, the operation efficiency is improved, and the operation and maintenance cost is reduced.

As an implementation, the tower 200 comprises a number of tower main materials 21. In the present embodiment, the tower main members 21 are made of four angle steels. One end of the tower main material 21 is fixedly connected with the ground, and the other end of the tower main material 21 extends upwards. The support tables 14 are disposed between the tower main members 21, and the outer edges of the support tables 14 are fixedly connected to the tower main members 21. The support table 14 may be fixedly connected to the tower main member 21 by welding, and the support table 14 may also be fixedly connected to the tower main member 21 by bolts.

As an implementation manner, the support platform 14 includes a plurality of support rods 141, the support rods 141 are fixedly connected to each other, and the support rods 141 are fixedly connected to the tower main material 21. The support bars 141 form a passing space 101 for a worker to pass through. A handrail 15 is provided on the upper side of the support table 14, and the handrail 15 is fixedly connected to the tower main member 21. Specifically, the handrail 15 is fixedly connected with the tower main material 21. Through the arrangement, when in operation, an operator can upwards pass through the passing space 101 and then step on the support rod 141 for operation, and the operation is convenient and fast. The armrest 15 improves the safety of the worker. During operation, the operator can tie a safety rope on the handrail 15 to prevent the operator from falling from the high altitude. A bird guide nest 16 is provided on the support platform 14 to prevent birds from damaging the terminal equipment.

Referring to fig. 2, as an implementation manner, the supporting platform 14 further includes a receiving frame 142 for receiving the solar module 11, the receiving frame 142 is substantially rectangular, and the solar module 11 is substantially rectangular and is adapted to the receiving frame 142. The support rod 141 is disposed outside the accommodating frame 142 and fixedly connected to the accommodating frame 142, one side of the solar module 11 is rotatably connected to one side of the accommodating frame 142, and the support base 14 is provided with a driving device 143 for driving the solar module 11 to rotate. Through the above arrangement, initially, the solar module 11 is inclined, that is, the solar module 11 and the horizontal plane form an acute angle, so that the solar module 11 can generate electricity by using solar energy. When the worker works on the support base 14, the driving device 143 rotates the solar module 11 so that the solar module 11 is substantially horizontal and positioned in the receiving frame 142. On one hand, the interference between the solar module 11 and an operator is avoided, and the operation flexibility of the operator is improved; on the other hand, the operator can step on the solar module 11 during operation, so that the activity space of the operator is increased, and the flexibility of operation is further improved.

Referring to fig. 2 and 3, as one implementation, the solar module 11 includes a power generating part 111, a rotating head 112, and a supporting part 113. The power generation unit 111 generates power by solar energy and charges the battery 13. The power generating part 111 is disposed at one side of the supporting part 113. Specifically, the power generation section 111 is attached to one side of the support section 113, and the support section 113 serves to support the power generation section 111, thereby improving stability of the power generation section 111. The support portion 113 is made of stainless steel, thereby improving the rigidity of the support portion 113. The support portion 113 includes a rotating edge 1131, a lifting edge 1132, a first support edge 1133, and a second support edge 1134, and the first support edge 1133 and the second support edge 1134 are disposed between the rotating edge 1131 and the lifting edge 1132. Specifically, the rotating edge 1131, the lifting edge 1132, the first supporting edge 1133 and the second supporting edge 1134 form a rectangle. The rotating edge 1131 is parallel to the lifting edge 1132, and the first supporting edge 1133 is parallel to the second supporting edge 1134. The receiving frame 142 includes a connecting edge 1421. The connecting edge 1421 and the rotating edge 1131 are parallel to each other. The rotating head 112 is rotatably connected to the rotating edge 1131, and the rotating head 112 is rotatably connected to one side of the accommodating frame 142. Specifically, the pivoting head 112 is pivotally connected to the midpoint of the pivoting edge 1131. The swivel head 112 is pivotally connected to the midpoint of the connecting edge 1421. The supporting portion 113 includes a rotation shaft 102, and the rotation shaft 102 passes through a midpoint of the rotation edge 1131 and a midpoint of the lifting edge 1132. By means of the rotary head 112, the solar module 11 can be rotated about the rotary shaft 102, and the solar module 11 can also be rotated about the connecting edge 1421.

Referring to fig. 3, initially, the power generating part 111 is located at an upper side of the supporting part 113. Referring to fig. 4, when the worker performs the work, the solar module 11 rotates to be horizontal around the connecting edge 1421 and enters the receiving frame 142. Referring to fig. 5, the solar module 11 is then rotated again by 180 degrees about the rotation shaft 102 so that the support portion 113 is located at the upper side of the power generation portion 111. The operator can step on the support part 113 during operation, which is convenient for the operator to operate. After the worker finishes working, the solar module 11 rotates 180 degrees around the rotating shaft 102, so that the power generating part 111 faces upward, and then the solar module 11 rotates around the connecting edge 1421 to return to the initial state. Referring to fig. 6, the first support rim 1133 and the second support rim 1134 are each provided with a support means 1135 for abutment with the upper side of the edge of the receiving frame 142. Referring to fig. 5, when the solar module 11 is horizontal and the support portion 113 faces upward, the support device 1135 abuts against the upper side of the accommodating frame 142, thereby improving the support performance of the support portion 113 and preventing the operator from collapsing the support portion 113. Specifically, the support device 1135 is disposed on a side of the support portion 113 away from the power generation portion 111. The supporting portion 113 is fixedly connected with a plurality of reinforcing ribs on the side far away from the power generating portion 111. Specifically, the reinforcing ribs are integrally formed with the support portion 113, thereby improving the rigidity of the support portion 113.

Referring to fig. 2 and 3, as an implementation manner, the driving device 143 includes a first driving rod 1431, a second driving rod 1432, and a driving rotation mechanism 1433, one end of the first driving rod 1431 is rotatably connected to the lifting edge 1132, the other end of the first driving rod 1431 is rotatably connected to the second driving rod 1432, the second driving rod 1432 is connected to the driving rotation mechanism 1433, and the driving rotation mechanism 1433 is disposed on the supporting platform 14. The solar module 11 includes a reference plane 103, the reference plane 103 is perpendicular to the horizontal plane, the reference plane 103 passes through a middle point of the connecting edge 1421 and a middle point of the lifting edge 1132, and the rotation shaft 102, the axis of the first driving rod 1431, and the axis of the second driving rod 1432 are located on the reference plane 103. The axis of the secondary drive rod 1432 is horizontal. The drive rotation mechanism 1433 can drive the second drive rod 1432 to move along the axis of the second drive rod 1432, and can also drive the second drive rod 1432 to rotate around the axis of the second drive rod 1432. Referring to fig. 4, when the operator works on the supporting platform 14, the driving and rotating mechanism 1433 drives the second driving rod 1432 to move away from the solar module 11, the first driving rod 1431 and the solar module 11 rotate relatively, and when the axis of the first driving rod 1431 coincides with the axis of the second driving rod 1432, the solar module 11 is horizontal and located in the accommodating frame 142. Referring to fig. 5, the driving rotation mechanism 1433 drives the second driving rod 1432 to rotate around the axis of the second driving rod 1432, and the second driving rod 1432 drives the first driving rod 1431 and the solar module 11 to rotate 180 degrees. When the worker finishes the job, the driving rotation mechanism 1433 drives the second driving rod 1432 to rotate 180 degrees around the axis of the second driving rod 1432, so that the power generation part 111 of the solar module 11 faces upward, then the driving rotation mechanism 1433 drives the second driving rod 1432 to move to the side close to the solar module 11, the second driving rod 1432 pushes the first driving rod 1431, the end of the first driving rod 1431 far away from the second driving rod 1432 jacks up the solar module 11, and the solar module 11 returns to the initial state. A return spring (not shown in the drawings) is provided between the first drive lever 1431 and the second drive lever 1432. When the solar module 11 is horizontal and the supporting portion 113 is upward, the return spring applies a driving force to an end of the first driving rod 1431 close to the second driving rod 1432, and when the second driving rod 1432 moves to a side close to the solar module 11, the driving force helps the end of the first driving rod 1431 far from the second driving rod 1432 to rotate and jack up the solar module 11.

Referring to fig. 3, the driving rotation mechanism 1433 includes a first cylinder 1433a fixedly connected to the supporting table 14, a first piston 1433b slidably connected in the first cylinder 1433a, a first piston rod 1433c connected to the first piston 1433b, and an air pump (not shown in the drawing) connected to the first cylinder 1433 a. The air pump is connected with the solar module 11. Specifically, the air pump is connected to the solar module 11 through the battery 13. The end of the first piston rod 1433c away from the first piston 1433b is provided with a sliding slot 1433d, the end of the second driving rod 1432 away from the first driving rod 1431 is provided in the sliding slot 1433d, the second driving rod 1432 is slidably connected with the sliding slot 1433d and rotatably connected with the sliding slot 1433d, the inner side of the sliding slot 1433d is provided with a spiral guide slot 1433e, the second driving rod 1432 is fixedly connected with a guide block 1433f, the guide block 1433f is provided in the guide slot 1433e, the sliding slot 1433d is provided with a first spring 1433g, one end of the first spring 1433g is connected with the second driving rod 1432, and the other end of the first spring 1433g is connected with the slot bottom of the sliding slot 1433 d.

Referring to fig. 3 and 7, initially, the guide block 1433f is located at an end of the guide slot 1433e adjacent to the first piston 1433b, and the first spring 1433g is in tension. Referring to fig. 4, when the operator works on the support platform 14, the air pump is operated, and the first piston 1433b moves to drive the second driving rod 1432 to move to the side far away from the solar module 11. Referring to fig. 5 and 8, when the axis of the first driving rod 1431 coincides with the axis of the second driving rod 1432, the solar module 11 is horizontal and located inside the receiving frame 142, the first piston 1433b continues to move towards the side far from the second driving rod 1432, the first spring 1433g is elongated, and under the action of the guide groove 1433e and the guide block 1433f, the second driving rod 1432, the first driving rod 1431 and the solar module 11 rotate 180 degrees, the supporting portion 113 is upward, and at this time, the guide block 1433f moves to the end of the guide groove 1433e far from the first piston 1433 b. After the worker finishes the work, the first piston 1433b moves to a side close to the second driving rod 1432 by the action of the air pump, the first spring 1433g shortens and restores, the second driving rod 1432, the first driving rod 1431 and the solar module 11 rotate 180 degrees under the action of the guide block 1433f and the guide groove 1433e, the power generation part 111 faces upward, the guide block 1433f is located at one end of the guide groove 1433e close to the first piston 1433b, and the first driving rod 1431 jacks up the solar module 11 as the first piston 1433b continues to move to a side close to the second driving rod 1432.

Referring to fig. 6 and 9, as an implementation manner, the support device 1135 includes a second cylinder 1135a fixedly connected to the support portion 113, a second piston 1135b slidably connected in the second cylinder 1135a, a second piston rod 1135c connected to the second piston 1135b, and a second spring 1135d disposed in the second cylinder 1135a, wherein the second piston rod 1135c includes a first end and a second end, the first end is connected to the second piston 1135b, the second end of the support device 1135 on the first support edge 1133 extends to a side away from the second support edge 1134, and the second end of the support device 1135 on the second support edge 1134 extends to a side away from the first support edge 1133. Referring to fig. 3, a first cavity 1433h is provided in the first cylinder 1433a, the first cavity 1433h is provided at a side of the first piston 1433b far from the first piston rod 1433c, a second cavity 1135e is provided in the second cylinder 1135a, the second cavity 1135e is provided at a side of the first piston 1433b close to the first piston rod 1433c, the air pump is communicated with the first cavity 1433h, the first piston 1433b is provided with a first air passage 1433k, the first piston 1433c is provided with a second air passage 1433m, one end of the first air passage 1433k is communicated with the first cavity 1433h, and the other end of the first air passage 1433k is communicated with the second air passage 1433 m. Referring to fig. 7, the second air passage 1433m communicates with the slide groove 1433d, the second driving rod 1432 is provided with a third air passage 1433n, the third air passage 1433n communicates with the slide groove 1433d, the first piston rod 1433c is further provided with a fourth air passage 1433p, and the fourth air passage 1433p communicates with the second cavity 1135 e.

Referring to fig. 3 and 7, in particular, initially, the solar module 11 is inclined, and the guide block 1433f is located at one end of the guide groove 1433e close to the first piston 1433b, where the third air passage 1433n and the fourth air passage 1433p are staggered and not communicated. When the operator works on the support table 14, the air pump uses the electric energy of the battery 13 to pump air into the first cavity 1433h, the air pressure in the first cavity 1433h is reduced, and the first piston 1433b moves to the side away from the second driving rod 1432. Referring to fig. 5 and 8, when the axes of the first and

second drive rods

1431 and 1432 coincide, the solar module 11 is horizontal, and the air pump continues to pump air into the first cavity 1433h, the first spring 1433g is elongated, the first piston 1433b continues to move to the side far away from the second drive rod 1432, and the first and

second drive rods

1431 and 1432 and the solar module 11 rotate 180 degrees synchronously under the action of the guide block 1433f and the guide slot 1433 e. At this time, the guide block 1433f moves to an end of the guide groove 1433e away from the first piston 1433b, and at this time, the third air passage 1433n and the fourth air passage 1433p communicate, so that the first cavity 1433h and the second cavity 1135e communicate. At this time, the supporting device is located at the upper side of the solar module, referring to fig. 6 and 9, as the air pump further pumps air into the first cavity 1433h, the air pressure in the second cavity 1135e decreases, the second piston rod 1135c moves to a side away from the second piston 1135b and moves above the edge of the accommodating frame 142, the second spring 1135d extends and is pulled, and when the operator steps on the supporting portion 113, the second piston rod 1135c is supported at the upper side of the accommodating frame 142, thereby improving the supporting performance of the supporting portion 113. When the worker finishes the operation, the air pump operates, the air pressure in the first cavity 1433h and the second cavity 1135e increases, the second spring 1135d shortens, under the action of the second spring 1135d, the second piston rod 1135c moves to a side close to the second piston 1135b, the second piston rod 1135c moves away from the upper side of the edge of the accommodating frame 142, i.e., the second piston rod 1135c and the receiving frame 142, are disengaged, as the air pressure in the first cavity 1433h becomes further greater, the first spring 1433g shortens, under the action of the first spring 1433g, the first piston rod 1433c moves towards the second drive rod 1432, under the action of the guide groove 1433e and the guide block 1433f, the second drive rod 1432, the first drive rod 1431 and the solar module 11 rotate 180 degrees, the power generation part 111 faces upward, the first piston rod 1433c continues to move towards the second drive rod 1432, the second drive rod 1432 pushes the first drive rod 1431, and the end of the first drive rod 1431 far away from the second drive rod 1432 jacks up the solar module 11.

It will be appreciated that modifications and variations are possible to those skilled in the art in light of the above teachings, and it is intended to cover all such modifications and variations as fall within the scope of the appended claims.

Claims

1. A multifunctional platform for a power transmission line tower comprises:

a solar module;

the information collection and communication module is connected with the solar module;

the multifunctional platform is characterized by further comprising a support table, wherein the support table is fixedly connected with the tower, and the solar module and the information collecting and communicating module are arranged on the support table;

the tower comprises a plurality of tower main materials, one ends of the tower main materials are fixedly connected with the ground, the other ends of the tower main materials extend upwards, the supporting table is arranged between the tower main materials, and the outer edge of the supporting table is fixedly connected with the tower main materials.

2. The multifunctional platform of the power transmission line tower as claimed in claim 1, wherein the support platform comprises a plurality of support rods, the support rods are fixedly connected with each other, the support rods are fixedly connected with the tower main material, and a passing space for workers to pass through is formed between the support rods.

3. The multifunctional platform for the power transmission line towers according to claim 2, wherein the support platform further comprises an accommodating frame for accommodating the solar module, the support rod is arranged on the outer side of the accommodating frame and fixedly connected with the accommodating frame, one side of the solar module is rotatably connected with one side of the accommodating frame, and a driving device for driving the solar module to rotate is arranged on the support platform.

4. The multifunctional platform for the transmission line towers and other poles according to claim 3, wherein the solar module comprises a power generation part, a rotating head and a supporting part, the power generation part is arranged on one side of the supporting part, the supporting part comprises a rotating edge, a lifting edge, a first supporting edge and a second supporting edge, the first supporting edge and the second supporting edge are arranged between the rotating edge and the lifting edge, the rotating head is rotatably connected with the rotating edge, the rotating head is rotatably connected with one side of the accommodating frame, and the first supporting edge and the second supporting edge are both provided with supporting devices which are used for being abutted to the upper side of the edge of the accommodating frame.

5. The multifunctional platform for transmission line towers according to claim 4, wherein the supporting device is arranged on one side of the supporting part, which is far away from the charging part.

6. The multifunctional platform for the power transmission line towers according to claim 4, wherein one side of the supporting part, which is far away from the power generation part, is fixedly connected with a plurality of reinforcing ribs.

7. The multifunctional platform for transmission line towers and other poles according to claim 4, wherein the driving device comprises a first driving rod, a second driving rod and a driving rotating mechanism, one end of the first driving rod is rotatably connected with the lifting edge, the other end of the first driving rod is rotatably connected with the second driving rod, the second driving rod is connected with the driving rotating mechanism, and the driving rotating mechanism is arranged on the supporting platform.

8. The multifunctional platform of the power transmission line tower as claimed in claim 7, wherein the driving rotation mechanism comprises a first cylinder fixedly connected with the support platform, a first piston slidably connected in the first cylinder, a first piston rod connected with the first piston, and an air pump connected with the first cylinder, the air pump is connected with the solar module, one end of the first piston rod away from the first piston is provided with a chute, one end of the second driving rod is arranged in the chute, the second driving rod is slidably connected with the chute and rotatably connected with the chute, a spiral guide groove is arranged on the inner side of the chute, the second driving rod is fixedly connected with a guide block, the guide block is arranged in the guide groove, a first spring is arranged in the chute, and one end of the first spring is connected with the second driving rod, the other end of the first spring is connected with the groove bottom of the sliding groove.

9. The multifunctional platform of claim 8, wherein the supporting device comprises a second cylinder fixedly connected to the supporting portion, a second piston slidably connected to the second cylinder, a second piston rod connected to the second piston, and a second spring disposed in the second cylinder, the second piston rod comprises a first end and a second end, the first end is connected to the second piston, the second end of the supporting device on the first supporting side extends to a side away from the second supporting side, the second end of the supporting device on the second supporting side extends to a side away from the first supporting side, a first cavity is disposed in the first cylinder, the first cavity is disposed on a side of the first piston away from the first piston rod, and a second cavity is disposed in the second cylinder, the second cavity is arranged on one side, close to the first piston rod, of the first piston, the air pump is communicated with the first cavity, the first piston is provided with a first air passage, the first piston rod is provided with a second air passage, one end of the first air passage is communicated with the first cavity, the other end of the first air passage is communicated with the second air passage, the second air passage is communicated with the chute, the second driving rod is provided with a third air passage, the third air passage is communicated with the chute, the first piston rod is provided with a fourth air passage, and the fourth air passage is communicated with the second cavity; when the guide block is positioned at one end of the guide groove far away from the first piston, the third air passage is communicated with the fourth air passage.