CN221073702U - Power transmission tower - Google Patents

Abstract

The application provides a power transmission tower, which comprises a tower body and a composite cross arm arranged on the tower body, wherein the composite cross arm comprises two post insulators, at least one cable-stayed insulator and a node fitting, the first ends of the two post insulators and the at least one cable-stayed insulator are connected with the tower body, the second ends of the two post insulators are connected together through the node fitting, the two post insulators are positioned on the same side of the tower body, the at least one cable-stayed insulator is positioned above the two post insulators, and the node fitting comprises: a first connection plate for connecting the second ends of the post insulators; the second connecting plate is arranged on the plate surface of the first connecting plate and is used for connecting the second end of the cable-stayed insulator; and a shielding ring mounted on the periphery of the first connection plate. Through the design, the space design of the node hardware fitting can be more compact, and the safety performance of the node hardware fitting can be ensured.

Description

Power transmission tower

Technical Field

The application relates to the technical field of power transmission, in particular to a power transmission tower.

Background

In the transmission tower, the node fitting generally plays a role of connecting an insulator and a hanging wire, but the current node fitting is complex in structure, large in occupied space and unfavorable for construction and maintenance on one hand, and is easy to damage and low in safety performance on the other hand in thunder and lightning weather.

Disclosure of utility model

In view of the above, the application provides a power transmission tower, which can reduce the occupied space of node hardware, ensure the compact structure of the node hardware, improve the safety performance of the node hardware and protect the node hardware.

In order to solve the above problems, the application provides a power transmission tower, which comprises a tower body and a composite cross arm arranged on the tower body, wherein the composite cross arm comprises two post insulators, at least one cable-stayed insulator and a node fitting, the two post insulators and the first end of the at least one cable-stayed insulator are connected with the tower body, the second end of the at least one cable-stayed insulator is connected together through the node fitting, the two post insulators are positioned on the same side of the tower body, the at least one cable-stayed insulator is positioned above the two post insulators, and the node fitting comprises: a first connection plate for connecting the second ends of the post insulators; the second connecting plate is arranged on the plate surface of the first connecting plate and is used for connecting the second end of the cable-stayed insulator; and a shielding ring mounted on the periphery of the first connection plate.

According to the application, the shielding ring is arranged on the first connecting plate, so that on one hand, the structure of the node fitting can be ensured to be compact, and on the other hand, the shielding ring has the function of balancing voltage, and can protect the node fitting, thereby ensuring the service life of the node fitting.

According to some embodiments of the application, the first connecting plate comprises a first surface and a second surface which are arranged opposite to each other, the second connecting plate is positioned on the first surface, the shielding ring is in a semi-surrounding structure and is connected with the first surface through the connecting bracket, so that the shielding ring is arranged around the first connecting plate.

The arrangement can play a role in effectively protecting the node hardware fitting.

According to some embodiments of the application, the node fitting further comprises: and the third connecting plate is arranged on the first surface and is connected with the second connecting plate on the side surface, and meanwhile, the third connecting plate is positioned in the shielding ring.

The setting of third connecting plate can strengthen the joint strength of first connecting plate and second connecting plate, also does benefit to construction and maintenance simultaneously.

According to some embodiments of the application, any two of the first, second, and third connection plates are disposed vertically.

The arrangement can ensure that the stress of the node hardware fittings is even.

According to some embodiments of the application, the node fitting further comprises: the wire hanging plate is installed on the second surface, the side face is connected with the second surface, the wire hanging plate is provided with two first wire hanging holes arranged at intervals and a first construction hole located between the two first wire hanging holes, and the two first wire hanging holes and the first construction hole are arranged at intervals along the direction parallel to the first connecting plate.

The wire hanging plate is more uniform in stress due to the arrangement, and convenient to construct and maintain.

According to some embodiments of the application, the first wire hanging hole and/or the first construction hole is/are used for hanging wire hanging hardware strings for hanging wires.

According to some embodiments of the application, the first connection plate is provided with a first mounting hole for mounting the post insulator; and a second mounting hole and a second construction hole are formed in the second connecting plate, and the second mounting hole is used for mounting the cable-stayed insulator.

The installation of cable-stayed insulator and pillar insulator can be guaranteed to above-mentioned setting on the one hand, and on the other hand also can promote the convenience of installation, maintenance.

According to some embodiments of the application, the power transmission tower further comprises: the first hinge piece is connected with the first end of the post insulator and the tower body so that the post insulator can rotate relative to the tower body; the second hinge piece is connected with the first end of the cable-stayed insulator and the tower body so that the cable-stayed insulator can rotate relative to the tower body.

The arrangement of the first hinge piece and the second hinge piece can enable the composite cross arm to rotate relative to the tower body after the post insulator is broken, so that the tower body is protected and prevented from being damaged by releasing excessive unbalanced tension through rotation.

According to some embodiments of the application, the tower comprises: a tower body; the first support frame and the second support frame are convexly arranged on the same side wall of the tower body, the first support frame is connected with the first end of the pillar insulator, and the second support frame is connected with the first end of the cable-stayed insulator.

The arrangement of the first support frame and the second support frame can ensure that the sizes of the composite cross arms arranged on the tower body are consistent.

According to some embodiments of the application, the power transmission tower comprises at least one arcing device, each arcing device comprising an arcing ring and an arcing end, the arcing ring being provided with a notch, the notch forming two ends of the arcing ring, the arcing end being located at one of the ends of the arcing ring, and the arcing end being bent in a direction away from the arcing ring.

Through the arrangement, the arcing function can be provided, and the power transmission tower is further protected.

The beneficial effects are that: according to the application, the shielding ring is arranged on the first surface of the first connecting plate, so that the space design of the whole node hardware fitting is more compact, meanwhile, the shielding ring can balance voltage, the whole node hardware fitting can be protected, and the service life of the node hardware fitting is further prolonged.

Further first articulated elements and second articulated elements's setting can make after the pillar insulator takes place to break, and compound cross arm can rotate relative body of a tower to release excessive unbalanced tension through rotating, protection body of a tower, avoid the body of a tower to receive the destruction.

The foregoing description is only an overview of the present application, and is intended to be implemented in accordance with the teachings of the present application in order that the same may be more clearly understood and to make the same and other objects, features and advantages of the present application more readily apparent.

Drawings

Various other advantages and benefits will become apparent to those of ordinary skill in the art upon reading the following detailed description of the preferred embodiments. The drawings are only for purposes of illustrating the preferred embodiments and are not to be construed as limiting the application. Also, like reference numerals are used to designate like parts throughout the accompanying drawings. In the drawings:

fig. 1 is a schematic structural diagram of an embodiment of a power transmission tower according to the present application;

fig. 2 is a schematic structural diagram of the node fitting in fig. 1;

FIG. 3 is a schematic view of the structure of the composite cross arm of FIG. 1;

Fig. 4 is a schematic structural view of the arcing device of fig. 1.

Detailed Description

The following description of the embodiments of the present application will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the application. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

Referring to fig. 1, the power transmission tower 10 of the present application includes a tower body 100 and a composite cross arm 200 disposed on the tower body 100, wherein the composite cross arm 200 includes a post insulator 210, a diagonal insulator 220 and a node fitting 230, the post insulator 210 and the diagonal insulator 220 are connected to the tower body 100 at first ends thereof, and connected to each other at second ends thereof via the node fitting 230.

Specifically, the tower body 100 may be a power transmission tower structure of a common structure such as a lattice type iron tower, a rod body or a composite material tower. The composite cross arm 200 may be provided on one side of the tower body 100 (as shown in fig. 1), or the composite cross arm 200 may be provided on multiple sides of the tower body 100. One side of the tower body 100 may be provided with one composite cross arm 200 (as shown in fig. 1), or a plurality of composite cross arms 200 may be disposed at intervals in the vertical direction.

The composite cross arm 200 comprises a post insulator 210, a cable-stayed insulator 220 and a node fitting 230, wherein a first end of the post insulator 210 is connected with the tower body 100, a second end of the post insulator is connected to the node fitting 230, a first end of the cable-stayed insulator 220 is connected with the tower body 100, a second end of the cable-stayed insulator is connected to the node fitting 230, and the node fitting 230 connects the post insulator 210 and the cable-stayed insulator 220 together to form an end of the composite cross arm 200 for hooking a wire.

In an application scenario, the number of the post insulators 210 is two, the number of the cable-stayed insulators 220 is one (as shown in fig. 1), the first ends of the two post insulators 210 and the cable-stayed insulators 220 are connected with the tower body 100, the second ends of the two post insulators 210 are connected together through the node fittings 230, the two post insulators 210 are located on the same side of the tower body 100, and the cable-stayed insulators 220 are located above the two post insulators 210. In another application scenario, the number of pillar insulators 210 is two, the number of cable-stayed insulators 220 is also two, and in yet another application scenario, the number of pillar insulators 210 is one, and the number of cable-stayed insulators 220 is also one. In summary, the present application does not limit the number of post insulators 210 and cable-stayed insulators 220.

Referring to fig. 1 and 2, the node fitting 230 includes a first connection plate 231, a second connection plate 232, and a shielding ring 233.

The first connection plate 231 is used for connecting the second end of the post insulator 210, and the second connection plate 232 is installed on the plate surface of the first connection plate 231 and is used for connecting the second end of the cable-stayed insulator 220; the shielding ring 233 is mounted at the outer periphery of the first connection plate 231. The plate surface of the first connecting plate 231 includes a first surface 231A and a second surface 231B disposed opposite to each other, and the second connecting plate 232 is located on the first surface 231A.

Specifically, the first connection plate 231 is connected to the pillar insulator 210, and the second connection plate 232 is connected to the cable-stayed insulator 220, that is, the pillar insulator 210 and the cable-stayed insulator 220 are connected to different connection plates. The post insulator 210 and the cable-stayed insulator 220 are connected with different connecting plates, so that concentrated stress at the same position can be avoided, and the service life of the node hardware fitting 230 is prolonged.

Further, the shielding ring 233 is installed on the first surface 231A, so that the space of the node fitting 230 is more compact, the shielding ring 233 can balance voltage, the function of protecting the node fitting 230 is achieved, the service life of the node fitting 230 is further prolonged, and the service life of the composite cross arm 200 can be prolonged.

In addition, as can be seen from fig. 1, the node fitting 230 of the present application has the advantages of simple structure, convenient processing, clear force transmission path and simple stress form.

Referring to fig. 2, the shielding ring 233 has a semi-surrounding structure, and is connected to the first surface 231A of the first connecting plate 231 by a connecting bracket, so that the shielding ring 233 is disposed around the first connecting plate 231.

Specifically, the shielding ring 233 has a semi-surrounding structure, i.e., it has a notch to avoid interference with the post insulator 210. Meanwhile, the shielding ring 233 is disposed at the periphery of the first connection plate 231, so that the first connection plate 231 can be effectively protected, and further, the node fitting 230 can be effectively protected. In an application scenario, as shown in fig. 2, the shape of the shielding ring 233 matches the contour of the first connection plate 231.

Of course, in some other embodiments, the shield ring may be a fully enclosed structure, so long as the second end of the post insulator does not interfere with the shield ring. Or the shielding ring may be provided on the first connection plate instead of being provided on the outer periphery of the first connection plate. In summary, the present application is not limited to the specific structure and specific installation position of the shielding ring 233.

Further, at least one connection bracket (not shown) is protruding from the shielding ring 233, and the connection bracket is connected to the first surface 231A.

Specifically, the connection bracket fixedly connects the shielding ring 233 with the first connection plate 231, and connection stability can be ensured.

In an application scenario, a connection hole (not shown) is formed in the first connection plate 231, and the connection bracket is connected to the first connection plate 231 through the connection hole.

In some other embodiments, the shielding ring may be connected to the first connection plate by welding or riveting.

Referring to fig. 2, the node fitting 230 further includes a third connection plate 234, the third connection plate 234 is mounted on the first surface 231A and laterally connected to the second connection plate 232, and the third connection plate 234 is located inside the shielding ring 233.

Specifically, the third connecting plate 234 is connected to the first connecting plate 231 and the second connecting plate 232 at the same time, so that the connection strength of the first connecting plate 231 and the second connecting plate 232 can be increased, and in addition, some through holes can be provided in the third connecting plate 234 for construction or maintenance. While the third connecting plate 234 is provided inside the shield ring 233 so that the shield ring 233 is well protected to the third connecting plate 234.

In some other embodiments, it may be optional not to provide the third connection plate.

Further, with continued reference to fig. 2, any two of the first connection plate 231, the second connection plate 232, and the third connection plate 234 are disposed vertically.

Specifically, the first connecting plate 231, the second connecting plate 232, and the third connecting plate 234 are perpendicular to each other, and when construction or maintenance is performed, the force acting on the third connecting plate 234 can be uniformly distributed to the entire node fitting 230, so that the node fitting 230 can be protected to the maximum extent.

With continued reference to fig. 2, the shielding ring 233 has a plane-symmetrical structure, and the symmetry plane of the shielding ring 233 is parallel to the first connecting plate 231. Specifically, the symmetry plane of the shielding ring 233 is parallel to the first connection plate 231, and the voltage balancing effect of the shielding ring 233 can be improved.

Further, in other embodiments, the number of shielding rings is plural, and a plurality of shielding rings are stacked.

Specifically, on the first surface, a plurality of shielding rings can be stacked, the shielding rings can be connected through a connecting bracket, and also can be in direct contact connection, and through the arrangement of the shielding rings in multiple layers, the voltage balancing effect of the shielding rings can be improved, so that the protection of the node hardware is improved, and the service life of the node hardware is prolonged.

The number of the shielding rings 233 is not limited, and may be one or more.

Referring to fig. 2 and 3, the node fitting 230 further includes a wire hanging plate 235, the wire hanging plate 235 is mounted on the second surface 231B and connected to the second surface 231B, the wire hanging plate 235 is provided with two first wire hanging holes 2351 disposed at intervals and a first construction hole 2352 disposed between the two first wire hanging holes 2351, wherein the two first wire hanging holes 2351 and the first construction hole 2352 are disposed at intervals along a direction parallel to the first connecting plate 231.

Specifically, on the lower side of the first connection plate 231, a wire hanging plate 235 is provided to be connected with the first connection plate 231, wherein two first wire hanging holes 2351 provided to the wire hanging plate 235 are used to mount the wire hanging hardware string 310, and the first construction holes 2352 are used for construction or maintenance. The two first wire hanging holes 2351 and the first construction hole 2352 are arranged at intervals in parallel along the direction parallel to the first connecting plate 231, so that the uniformity of the stress of the node fitting 230 can be ensured.

For a clearer description, referring to fig. 1 to 3, the node fitting 230 is connected to the wire hanging fitting strings 310 through wire hanging plates 235, each of the first wire hanging holes 2351 corresponds to one wire hanging fitting string 310, each of the wire hanging fitting strings 310 corresponds to 2 wires 320, and in this embodiment, the transmission tower 10 hangs single-phase four split wires using the composite cross arm 200.

When in use, the first construction hole 2352 is used to mount the wire hanging hardware string 310 according to the requirement, and the first wire hanging hole 2351 is used to perform construction or maintenance, that is, the functions of the first wire hanging hole 2351 and the first construction hole 2352 can be interchanged. Meanwhile, in other embodiments, the first wire hanging hole and the first construction hole may be set to other numbers as long as the wire hanging requirement is satisfied.

Referring to fig. 2, the first connection plate 231 is perpendicular to the plane of symmetry of the board, the second connection plate 232 is parallel to the plane of symmetry of the board, and the wire hanging plate 235 is parallel to the plane of symmetry of the board, that is, the overall structure formed by the first connection plate 231, the second connection plate 232 and the wire hanging plate 235 is a symmetrical structure, and the arrangement can make the stress of the node hardware 230 on the connection post insulator 210 and the cable-stayed insulator 220, on the mounting of the wire hanging hardware string 310 and during construction and maintenance more uniform, and can effectively protect the composite cross arm 200.

Referring to fig. 1 and 2, a first mounting hole 2311 is formed in the first connection plate 231 for mounting the post insulator 210; the second connecting plate 232 is provided with a second mounting hole 2321 and a second construction hole 2322, the second mounting hole 2321 is used for mounting the cable-stayed insulator 220, and the second construction hole 2322 is used for construction or maintenance.

Specifically, the number of the first mounting holes 2311 may be 1 or more, and may be set according to the actual situation, so that the mounting connection between the post insulator 210 and the first connection plate 231 may be facilitated by providing the first mounting holes 2311. The number of the second mounting holes 2321 may be 1 or a plurality of second mounting holes 2321, and the cable-stayed insulator 220 and the second connection plate 232 can be conveniently mounted and connected by arranging the second mounting holes 2321 according to actual conditions. The second construction hole 2322 is used to facilitate construction, providing more options for the constructor.

Referring to fig. 1, power transmission tower 10 further includes a first hinge 410 and a second hinge 420. The first hinge 410 connects the first end of the post insulator 210 with the tower body 100 such that the post insulator 210 is rotatable with respect to the tower body 100; the second hinge 420 connects the first end of the cable-stayed insulator 220 with the tower body 100 such that the cable-stayed insulator 220 is rotatable relative to the tower body 100.

Specifically, the first hinge 410 and the second hinge 420 are rotatable connectors, which enable the post insulator 210 to rotate relative to the tower body 100, and the cable insulator 220 to rotate relative to the tower body 100.

In an embodiment, when the number of the pillar insulators 210 is two and the number of the cable-stayed insulators 220 is one, the two pillar insulators 210 and the cable-stayed insulator 220 form a stable triangular pyramid structure, and the two pillar insulators 210 and the tower body 100 also form a stable triangular structure. Normally, the first hinge 410 and the second hinge 420 support rotation, but the composite cross arm 200 cannot rotate with respect to the tower body 100 because of the stable structure of the two post insulators 210, the one diagonal insulator 220, and the tower body 100.

When one of the post insulators 210 breaks, the cable-stayed insulator 220 and the rest of the post insulators 210 are driven to rotate relative to the tower body 100 due to abrupt load change, so that the load is released through rotation, the composite cross arm 200 is prevented from being completely damaged, and the composite cross arm 200 can also play a role in mounting wires before the composite cross arm 200 is maintained, and larger accidents are prevented.

Further, since the design has a certain effect of releasing load, the design specification can be reduced in the design, and the application can adopt a design with smaller broken load relative to a fixed connection mode, so that the manufacturing cost can be reduced.

Meanwhile, in the prior art, the post insulator 210 is usually connected with the tower body 100 by adopting a form of a butt strap (including a plugboard and the like), and the connection mode is actually between the fixedly connected mode and the hinged mode, but when the corresponding compressive stability calculation is performed, the post insulator 210 and the diagonal insulator 220 are always assumed to be hinged boundary conditions for safety, so that design redundancy is caused, but in the design of the application, the connection mode of the post insulator 210 and the diagonal insulator 220 and the tower body 100 is hinged, and is consistent with the boundary condition assumption in a stability calculation formula, so that the design redundancy can be avoided.

The above description is given of the embodiments of the two post insulators 210 and the one cable-stayed insulator 220, but the present invention is also applicable to the embodiments of the two post insulators 210 and the two cable-stayed insulators 220.

In some other embodiments, the composite cross arm and the tower body can also be connected through a fixed connecting piece, and at the moment, the post insulator and the cable-stayed insulator can not rotate relative to the tower body.

Referring to fig. 1, a tower body 100 includes a tower body 110, a first support frame 120 and a second support frame 130. The first supporting frame 120 and the second supporting frame 130 are convexly arranged on the same side wall of the tower body 110, the first supporting frame 120 is connected with the first end of the pillar insulator 210, and the second supporting frame 130 is connected with the first end of the cable-stayed insulator 220.

Specifically, the first support frame 120 may be adaptively designed according to the relative position and angle between the post insulator 210 and the tower body 100, and the second support frame 130 may be adaptively designed according to the relative position and angle between the cable-stayed insulator 220 and the tower body 100.

The arrangement of the first support frame 120 and the second support frame 130 can facilitate and efficiently maintain the composite cross arm 200 and the tower body 100 on one hand; on the other hand, when a plurality of composite cross arms 200 are provided on the tower body 100, since the interval between the composite cross arms 200 and the tower body 100 can be adjusted through the first support frame 120 and the second support frame 130, the sizes of the plurality of composite cross arms 200 can be uniform, thereby improving the production efficiency.

In some other embodiments, the post insulator and the cable-stayed insulator may be directly mounted on the tower body without mounting the first support frame and the second support frame. Or only the first supporting frame is installed, but the second supporting frame is not installed, at this time, the pillar insulator is connected with the first supporting frame, and the cable-stayed insulator is directly installed on the tower body, so that the cable-stayed insulator is not limited.

Referring to fig. 1, 3 and 4, the power transmission tower 10 includes at least one arcing device 500, each arcing device 500 includes an arcing ring 510 and an arcing end 520, the arcing ring 510 is provided with a notch 530, the notch 530 enables the arcing ring 510 to form two ends, the arcing end 520 is located at one of the ends of the arcing ring 510, and the arcing end 520 is bent towards a direction away from the arcing ring 510. Wherein, the arcing terminal 520 is an arcing ball or arcing rod with smooth surface.

Specifically, the arc striking device 500 may be selectively installed at both ends of the post insulator 210 and the cable-stayed insulator 220 for striking an arc, and may function to protect the composite cross arm 200. Wherein, the arcing ring 510 is provided with the notch 530, on the one hand, can save material, on the other hand, can avoid arcing end 520 to contact with arcing ring 510, can guarantee the arcing effect of arcing end 520, simultaneously, will arcing end 520 is buckled towards the direction that deviates from arcing ring 510, can further promote the arcing effect of arcing end 520.

With continued reference to fig. 1, in order to further enhance the safety performance and ensure the service life of the composite cross arm 200, the two ends of the post insulator 210 are sleeved with equalizing rings.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present application, and not for limiting the same; although the application has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some or all of the technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit of the application, and are intended to be included within the scope of the appended claims and description. In particular, the technical features mentioned in the respective embodiments may be combined in any manner as long as there is no structural conflict. The present application is not limited to the specific embodiments disclosed herein, but encompasses all technical solutions falling within the scope of the claims.

Claims (10)

1. The utility model provides a transmission tower, its characterized in that, the transmission tower include the body of a tower with set up in compound cross arm on the body of a tower, compound cross arm includes two pillar insulators, at least one draws insulator and node gold utensil to one side, two pillar insulators, at least one draw the first end of insulator all with the body of a tower is connected, the second end is passed through the node gold utensil links together, two pillar insulators is located the same side of body of a tower, at least one draw the insulator to one side and be located two pillar insulator's top, the node gold utensil includes:

a first connection plate for connecting the second ends of the post insulators;

the second connecting plate is arranged on the plate surface of the first connecting plate and is used for connecting the second end of the cable-stayed insulator;

and a shielding ring mounted on the periphery of the first connection plate.

2. The power transmission tower according to claim 1, wherein the first connection plate comprises a first surface and a second surface which are arranged opposite to each other, the second connection plate is located on the first surface, the shielding ring is in a semi-surrounding structure, and the shielding ring is connected with the first surface through a connection bracket, so that the shielding ring is arranged around the first connection plate.

3. The power transmission tower of claim 2, wherein the node fitting further comprises:

And the third connecting plate is arranged on the first surface, the side surface of the third connecting plate is connected with the second connecting plate, and meanwhile, the third connecting plate is positioned in the shielding ring.

4. A transmission tower according to claim 3, wherein any two of the first, second and third connection plates are arranged vertically.

5. The power transmission tower of claim 2, wherein the node fitting further comprises:

The wire hanging plate is installed on the second surface, the side face of the wire hanging plate is connected with the second surface, the wire hanging plate is provided with two first wire hanging holes arranged at intervals and a first construction hole located between the two first wire hanging holes, and the two first wire hanging holes and the first construction hole are arranged at intervals along the direction parallel to the first connecting plate.

6. The power transmission tower according to claim 5, wherein the first wire hanging hole and/or the first construction hole is/are internally provided with a wire hanging fitting string for hanging wires.

7. The power transmission tower according to claim 1, wherein,

The first connecting plate is provided with a first mounting hole for mounting the post insulator;

The second connecting plate is provided with a second mounting hole and a second construction hole, and the second mounting hole is used for mounting the cable-stayed insulator.

8. The power transmission tower of claim 1, further comprising:

a first hinge connecting the first end of the post insulator with the tower body so that the post insulator is rotatable relative to the tower body;

the second hinge piece is connected with the first end of the cable-stayed insulator and the tower body, so that the cable-stayed insulator can rotate relative to the tower body.

9. The power transmission tower of claim 1, wherein the tower body comprises:

A tower body;

The first support frame and the second support frame are convexly arranged on the same side wall of the tower body, the first support frame is connected with the first end of the pillar insulator, and the second support frame is connected with the first end of the cable-stayed insulator.

10. The power transmission tower according to claim 1, characterized in that it comprises at least one arcing device, each arcing device comprising an arcing ring and an arcing end, the arcing ring being provided with a notch, the notch forming the arcing ring into two ends, the arcing end being located at one of the ends of the arcing ring, and the arcing end being bent in a direction away from the arcing ring.