BR112019001514B1 - CROSS ARM APPLIED TO AN ANGULAR TOWER, ANGULAR TOWER, CROSS ARM APPLIED TO A TENSION TOWER AND TENSION TOWER - Google Patents

Abstract

It is a transverse arm (110), one end of which is connected to a tower body (101), and the end of the transverse arm (110) away from the tower body (101) is a free end for connecting a lead wire (103). The free end comprises an end connecting a portion (111) and an extension portion (112). The extension part (112) is fixed to the end connection part (111). In a horizontal projection, the extension part (112) projects from the end connection part (111) and the lead wire (103) is connected to the extension part (112). The angle between the extension part (112) and the center line of the cross arm (110) is greater than the angle between the lead wire (103) and the center line of the cross arm (110). The free end of the cross arm (110) is further provided with a jumper device wire (120), which is arranged horizontally in the end connection part (111) and is used to hold the jumper wire. When using the extension part, the distance between the conduction wire and the tower body can be increased under the condition that the turning angle is met, thus the requirement that an electrical gap between (...).

Description

Technical Field

[001] This invention relates to a technical field of power transmission and transformation devices and, more particularly, to a transverse arm, and to an angle tower and a tension tower including the same.

Fundamentals

[002] In an overhead transmission line, a transmission tower functions to support a conduction wire. Specifically, the conduction wire is supported by a transverse arm fixed to the transmission tower. The specific connecting means supports the conduction wire at a free end of the transverse arm of the transmission tower.

[003] An angle tower is a transmission tower used to change a route direction of a line that the route direction is required to be changed. As shown in Figure 1, a conventional angle tower 10 has an outer corner 11 and an inner corner 12. The lead wire 13 at the inner corner 12 tends to be far from the angle tower 10, and the lead wire 14 at the outer corner 11 tends to first approach and then move away from the angle tower 10. There is a requirement for a minimum electrical clearance between the lead wire and the angle tower 10. In general, the distance between the lead wire and the tower angle 10 is increased by increasing the length of the cross arm to meet the electrical clearance requirement, but an excessively long cross arm multiplies production difficulties.

[004] A tension tower is commonly used to support unbalanced tension, and the force on the driving wire is generally transferred to the tower body by a tension column. The voltage tower includes a line voltage tower, an angle tower and a terminal tower, which can bear the horizontal load generated by conduction wires and ground wires. The lead wires on both sides of the voltage tower need to be connected by a jumper wire. As shown in Figure 2, in a conventional voltage tower 20, the jumper wire needs to be carried out when using a voltage insulating column 21 and related fittings. The use of stress insulating column 21 and fittings makes the vertical spacing between the cross arms 22 very wide, and causes the tower head 23 to have a complicated structure with a large size, which is inconvenient for maintenance and installation . This makes the tension tower 20 expensive, the load caused by the driving wire and the wind load on the tower head are large, and the tower body is heavy.

summary

[005] In view of the disadvantages of the prior art, an object of the present disclosure is to provide a transverse arm that is used in an angled tower to support a conduction wire, so that the electrical gap between the conduction wire and the conduction body tower can be satisfied without increasing the length of the transverse arm. Another object of the present disclosure is to provide a cross arm that can be used in a voltage tower to support a conductor wire, so that voltage insulators and complicated connections between fittings can be canceled. Therefore, the interlayer spacing of the conduction wires is narrow, and the tower head size of the tension tower is reduced. As a result, the structure is simplified and the cost is reduced.

[006] In order to achieve the aforementioned objectives, the present disclosure adopts the following technical solutions.

[007] According to one aspect of the present disclosure, a transverse arm applied to an angle tower is provided. Said angular tower includes a tower body. One end of said transverse arm is connected to said tower body, and another end of said transverse arm distant from said tower body is a free end for connecting a conduction wire. Said free end comprises an end connecting member and an elongated member fixed to said end connecting member. In a horizontal projection, said elongated member extends outwardly from said end connecting member. Said lead wire is connected to said elongated member. An angle between said elongated member and a center line of said transverse arm is greater than an angle between said lead wire and said center line of said transverse arm.

[008] There is a requirement on the minimum electrical clearance between the conduction wire and the tower body. Electrical clearance refers to the shortest space distance from the conduction wire to the tower body. Minimum electrical clearance can avoid causing simultaneous ignition and ensure personal safety. According to the present disclosure, in horizontal projection, said elongate member extends outwardly from said free end in a direction parallel to or distant from said tower body, such that the distance between two points suspended from the two conduction wires in the corner can be increased. Then, a distance between the conduction wire and the tower body can be increased, that is, the electrical gap between the conduction wire and the tower body is increased without changing the length of the transverse arm.

[009] Preferably, said elongated member is disposed on both sides of said end connecting member. The two lead wires at the corner can be suspended on the elongated members arranged on both sides of the end connecting member respectively, so that the distance between the lead wire and the tower body can be increased.

[010] Preferably, said elongated member is disposed on said end connecting member, and the two conduction wires at one corner are respectively connected to both ends of said elongated member. The elongated member can be mounted on the end connecting member as a whole, which only needs to be fixed to the free end.

[011] Preferably, said elongated member is joined by a plurality of support segments. The appropriate number of brackets can be chosen to mount an elongated member of a desired length as required to meet the electrical clearance requirement between the conduction wire and the tower body. Furthermore, when the elongated member needs to be long, it is flexible to mount such elongated member in a form of multi-segment supports.

[012] Preferably, at least one reinforcing member is disposed on said elongated member. The arrangement of the reinforcing member can improve the strength and structural stability of the elongated member.

[013] Preferably, said at least one reinforcing member is connected to said end connecting member and said end connecting member. The reinforcing member, the elongated member and the end connecting member can form a stable triangular structure that further increases the strength of the elongated member.

[014] Preferably, at least one auxiliary member is disposed between said reinforcing member and said elongated member, and said auxiliary member is connected to said reinforcing member and said elongated member. An arrangement of the auxiliary member further increases the rigidity of the elongated member.

[015] Preferably, said elongated member is disposed in an external corner of said angular tower. At the outer corner, the lead wire at the corner first approaches and moves away from the tower body, thus making the electrical gap between the lead wire and the tower body not meet the requirement. The arrangement of the elongated member at the outer corner of the angle tower can increase the distance between the two conduction wires and the tower body at the outer corner.

[016] Preferably, said transverse arm is a composite transverse arm.

[017] An angle tower is also provided in accordance with the present disclosure. The angle turret includes the turret body and the transverse arm mentioned above. The angle tower can meet the requirement for electrical clearance between the conduction wire and the tower body without increasing the length of the cross arm.

[018] According to another aspect of the present disclosure, a transverse arm applied to the tension tower is provided. Said tension tower includes a tower body. One end of said transverse arm is connected to said tower body, and the other end of said transverse arm distant from the tower body is a free end for connecting a conduction wire. Said free end is provided with an end connecting member and a jumper device. Said jumper device is arranged horizontally on said end connection member and configured to be suspended with a jumper wire.

[019] The jumper device is arranged horizontally on the end connection member, then the jumper device will not occupy the vertical space, thus the spacing between the layers of the conduction wires can be narrow. And voltage isolators and complicated connections between fittings can be canceled. Thus, the tower head size of the tension tower is reduced, the structure is simplified, and the cost is reduced.

[020] Preferably, said jumper device is a composite column insulator, one end of said composite column insulator is connected to said end connection member, and the other end of said composite column insulator is suspended with said jumper wire. The jumper device is configured as a composite column insulator, which can optimize the electric field of the cross arm.

[021] Preferably, said composite column insulator is suspended with said jumper wire by a connecting fitting. It is convenient for connection and installation.

[022] Preferably, said tension tower is an angular tower. Said end connecting member is further connected to an elongated member. In a horizontal projection, said elongated member extends outwardly from said end connecting member. Said lead wire is connected to said elongated member. An angle between said elongated member and the center line of said transverse arm is greater than an angle between said conduction wire and the center line of said transverse arm.

[023] In an angled tower, there is a requirement regarding the minimum electrical clearance between the conduction wire and the tower body. Electrical clearance refers to the shortest space distance from the conduction wire to the tower body. Minimum electrical clearance can prevent simultaneous ignition and ensure personal safety. According to the present disclosure, in horizontal projection, said elongated member extends outwardly from said free end in a direction parallel to or distant from said tower body. The distance between the two suspension points of the two conduction wires on both sides of the tower body can be increased. Then, the distance between the conduction wire and the tower body can be increased, that is, the electrical gap between the conduction wire and the tower body can be increased without changing the length of the transverse arm.

[024] Preferably, said elongated member is disposed on both sides of said end connecting member. The two conduction wires on both sides of the tower can be suspended on the elongated members arranged on both sides of the end connecting member, so that the distance between the conduction wire and the tower body can be increased.

[025] Preferably, said elongated member is disposed in said end connecting member, and the two conduction wires on both sides of said tower body are respectively connected to both ends of said elongated member. The elongated member can be mounted on the end connecting member as a whole, which only needs to be fixed to the free end.

[026] Preferably, at least one reinforcing member is disposed on said elongated member. The arrangement of the reinforcing member can increase the strength and structural stability of the elongated member.

[027] Preferably, said at least one reinforcing member is connected to said elongated member and said end connecting member. The reinforcing member, the elongated member and the end connecting member can form the stable triangular structure which further increases the strength of the elongated member.

[028] Preferably, said transverse arm is a composite transverse arm.

[029] The tension tower is provided in accordance with the present disclosure. The tension tower includes said tower body and said transverse arm. The tower head size of the tension tower is small, the material cost is saved, and the installation is convenient.

Description of the Drawings

[030] Figure 1 is a top view of a conventional angular tower; Figure 2 is a schematic view of a conventional tension tower; Figure 3 is a top view of an angle tower according to example one of the present disclosure; Figure 4 is an enlarged partial view of a free end of the transverse arm shown in Figure 3; Figure 5 is a schematic view of a free end of a transverse arm according to example two of the present disclosure; Figure 6 is an enlarged partial view of a free end of the transverse arm shown in Figure 5; Figure 7 is a schematic view of an angle tower according to example three of the present disclosure; figure 8 is a schematic view of a tension tower according to example four of the present disclosure; figure 9 is a schematic view of a tension tower according to example five of the present disclosure; Figure 10 is an enlarged partial view of a free end of the transverse arm shown in Figure 9; Figure 11 is a top view of a tension tower according to example six of the present disclosure; And Figure 12 is an enlarged partial view of a free end of the transverse arm shown in Figure 11.

Detailed Description

[031] The specific modalities of this disclosure will be disclosed here upon request. However, it should be understood that the embodiments presented here are only examples of the present disclosure and can be embodied in various ways. Accordingly, the details herein should not be construed as being limiting, but simply serve as the basis of the claims and representative basis for teaching those skilled in the art to variously apply the disclosure of any suitable means in practice, which includes the use of various features presented here and the combination with features that may not be explicitly presented here.

[032] A transverse arm in accordance with an aspect of the present disclosure will be described below when considering an angle tower as an example

Example One

[033] Figure 3 is a schematic view showing the use of an angle tower 100 at a corner of a line. The angle tower 100 includes a tower body 101 and transverse arms 110 disposed on the tower body 101. Leading wires 103 at the corner are suspended from the transverse arms 110 respectively. In this example, the lead wires 103 have a corner angle of 120 degrees.

[034] In this example, the transverse arm 110 is a V-shaped composite transverse arm with an open end connected to the tower body 101, and an apex that serves as a free end that is used to connect the conduction wire 103. The cross arm 110 includes two cross arm insulations 113 and the free end. The two cross-arm insulations 113 are secured by an end fitting 111 at the free end.

[035] Figure 4 shows an enlarged partial view of a free end of the transverse arm. The free end of the transverse arm includes an end fitting 111, elongated members 112, and a jumper device 120. Specifically, the elongated members 112 are respectively disposed on both sides of the end fitting 111. Each elongated member 112 has a one end connected to the end fitting 111 and the other end connected to a lead wire 103 on the same side of the elongated member. The jumper device 120 is attached to the end fitting 111 to support the jumper wire.

[036] In this example, the angle between the conduction wire 103 and the center line of the transverse arm 110 is 60 degrees. The elongated member 112 is arranged horizontally at the free end, and an angle between the elongated member 112 and the center line of the transverse arm 110 is 90 degrees. The arrangement of the elongated member 112 is equivalent to extending a virtual intersection of the two corner lead wires 103 on the same side of the tower body 101. Thus, the distance between the lead wire 103 and the tower body is increased. The electrical clearance between the lead wire 103 and the tower body 101 can be satisfied without changing the length of the cross arm 110.

[037] In order to explain intuitively, figure 3 can be compared to figure 1. Figure 1 shows an angled tower 10 without an elongated member, while figure 3 shows an angled tower 100 with an elongated member 112 in accordance with with this modality. Both the angle towers in figure 1 and figure 3 have the same corner angle and the same cross-arm length. A distance L2 from the lead wire 103 to the tower body 101 in figure 3 is greater than the distance L1 from the lead wire 13 to the tower body in figure 1.

[038] Alternatively, by drawing a line parallel to the lead wire 103 with any point on the end fitting 111 as a starting point, it is obvious that the distance from the parallel line drawn to the tower body 101 is less than the distance from the conduction wire 103 to the tower body 101. That is, it is easier to satisfy the electrical gap between the conduction wire and the tower body when using the transverse arm provided with the elongated member 112 on the angle tower.

[039] In this embodiment, the elongated member 112 is arranged horizontally at the free end so that the angle between the elongated member 112 and the center line of the transverse arm 110 can be directly compared. However, it is obvious that the elongated member cannot be completely in the horizontal plane either. The elongated member can be displaced by an angle in the vertical plane, as long as it is in the horizontal projection, the angle between the elongated member and the center line of the transverse arm is greater than the angle between the leading wire on the same side and the center line of the transverse arm.

[040] Furthermore, two reinforcing members are arranged at the free end of the transverse arm 110. These two reinforcing members include an inclined member 116 and an auxiliary member 117. The inclined member 116 and the elongated member 112 form a shaped structure of V, that is, the end parts of the inclined member 116 and the elongated member 112 are fixed to a connecting plate 118 to form a V-shaped apex, and the other end of the inclined member 116 is fixed to the end fitting 111. The arrangement of the inclined member 116 increases the rigidity and strength of the elongated member 112. The auxiliary member 117 is connected to the inclined member 116 and the elongated member 112, thus the V-shaped structure formed by the inclined member 116 and the elongated member 112 is reinforced, and the rigidity and strength of the elongated member 112 are further increased.

[041] Due to the use of the elongated member 112, the transverse arm 110 is prevented from being too long, so that the angle tower provided with transverse arms 110 can avoid the situation that the electrical gap between the conduction wires is not satisfied . The angular tower is light and the line corridor is narrow.

[042] The number of corner lead wires is not the point of invention of the present disclosure, so the corner lead wires can also be split wires. In this example, the elongated member 112 may be disposed at the outer corner of the angle tower 100, but the elongated member 112 may also be disposed at the inner corner. The leading wire at the outer corner is close to the first tower body and then far from the tower body at the outer corner, while the leading wire at the corner is directly far from the tower body at the inner corner, therefore compared to the inner corner, it is more necessary to provide an elongated member at the outer corner.

Example Two

[043] As shown in figure 5 and figure 6, In this example, an elongated member 212 is fixed to an end fitting 211 as a whole, and the lead wires 203 at a corner are connected to both ends of the elongated member 212 , respectively. In contrast to Example One, the elongated member 212 in this example is formed by joining five supports 219 with different lengths. A suitable number of brackets can be chosen to mount an elongated member of a desired length as required to meet the electrical clearance between the conduction wire and the tower body. Furthermore, when an elongated member needs to be long, it is flexible for mounting in a form of multi-segment brackets. In this example, a reinforcing member and an auxiliary member are also arranged at the free end of the transverse arm, whose functions and structures are the same as in example One, and are not described in detail here.

Example Three

[044] The elongated member provided in this disclosure is not limited to the transverse member structure, material, corner angle of the conduction wire and others, to which it is applied. As shown in Figure 7, In this example, the transverse arm 310 in the angle tower 300 is a line-shaped transverse arm. The lead wire 303 has a corner angle of 100 degrees, and an angle between the lead wire 303 at the corner and the center line of the cross arm 310 is 50 degrees. In this example, the elongated members are arranged at both the inner and outer corners.

[045] Specifically, the cross arm 310 includes a cross arm insulator 313 and a free end distant from the tower body 301. The free end includes an end fitting 311 and an elongated member 312 connected to the end fitting 311. The elongated member 312 is a rectangular plate that has an inclination angle of 60 degrees in a vertical plane, and two angles of 70 degrees and 110 degrees relative to the center line of the transverse arm 310 respectively. Since any angle between the elongated member 312 and the centerline of the transverse arm 310 is greater than the angle between the lead wire 303 and the centerline of the transverse arm 310, the transverse arm 310 in this example can satisfy the electrical gap between the lead wire 303 and the tower body 301.

[046] In this example, one end of the end fitting 311 is a sleeve connected to the cross-arm insulator 313. Another end of the end fitting 311 is a connecting plate fixed to the elongated member 312. The end fitting may include any member of suitable connection, i.e. that can be fixed to the elongated member as known to the person skilled in the art. Furthermore, the lead wire may be connected to the elongated member by any suitable connecting means known to the person skilled in the art, for example, by being secured through a wire clamp.

[047] From this point on, a transverse arm according to another aspect of the present disclosure will be described with an example of a tension tower.

Example Four

[048] As shown in Figure 8, in this example, the voltage tower 400 is used for a double-circuit power transmission line and is also used to change the line direction, so it can also be considered as a tower angular. The voltage tower 400 as an angle tower includes a tower body 401, and six transverse arms 410 arranged on the voltage tower 400 for connecting three-phase conduction wires, respectively. One end of the transverse arm 410 is connected to the tower body 401, and the other end of the transverse arm 410 away from the tower body 401 is a free end for connecting the conduction wire 403. The free end of the transverse arm 410 is provided with an end connection member 411 and a jumper device 420. The jumper device 420 is arranged horizontally on the end connection member 411 when suspended with the jumper wire 402. In this example, the arrangement of the jumper device 420 replaces the columns voltage insulators and the complex plug-in connection configurations associated with the prior art. The vertical distance between the cross arms of each phase is reduced, thus the size of the tower head of the tension tower 400 is reduced as well. The material of 401 turret body is saved, the structure is simplified, and the cost is reduced.

[049] Specifically, the tower body 401 may be a lattice-type iron tower, or it may be a rod body, or other forms of transmission tower structure, such as a composite tower. In this example, the jumper device 420 includes a composite column insulator 421. The composite column insulator 421 includes an inner core rod and coatings outside the core rod. The core rod is molded by pultrusion from fiberglass impregnated with epoxy resin. The liners are produced from high temperature vulcanized silicone rubber and integral vacuum injection molded outside the core rod. Both ends of the composite column insulator 421 are glue-mounted flanges 422 for connecting the end connecting member 411 or wire clamps, so that the jumper wires 402 can be suspended.

[050] As shown in Figure 8, in this example, the flange 422 at one end of the composite column insulator 421 is connected to the end connection member 411, for example, by means of bolting, welding, etc. The composite column insulator 421 extends horizontally from the end connecting member 411 in a direction away from the tower body 401, and a jumper wire 402 is directly suspended to the flange 422 at the other end. The middle part of the jumper wire 402 is suspended from the composite column insulator 421. Two ends of the jumper wire 402 are connected to the corner lead wires 403 on both sides of the cross arm. Therefore, the lead wires are connected.

[051] The conventional voltage insulating column is suspended from the end part of the transverse arm and is arranged vertically between two adjacent transverse arms. In contrast, the arrangement of the composite column insulator 421 in the present disclosure can eliminate the voltage insulating column. Since the composite column insulator 421 is arranged horizontally on the end connecting member 411, the composite column insulator 421 itself does not occupy any vertical distance between the upper and lower adjacent transverse arms of different phases. In the vertical plane, the 402 jumper wire only drops a small radian. Therefore, there is no need to provide a large vertical space between the upper and lower adjacent cross arms, so the upper, middle and lower three-stage cross arms can be arranged more compactly on the condition of satisfying the requirements of electrical performance. Then the tower head size of tension tower 400 can be smaller, thus the structure is simplified and the cost is reduced.

[052] In this example, each phase of the cross arm 410 of the voltage tower 400 includes a composite column insulator 421. Obviously, there may be only one phase or two phases of cross arms 100 that include the composite column insulator 421 in the voltage tower. voltage 400. When the voltage tower 400 is used for a single circuit transmission line or more than one transmission line, it is only necessary to provide a corresponding number of cross arms 410 according to the current operating conditions. Furthermore, when the voltage tower is a line voltage tower or a terminal tower, the same jumper device 420 can also be applied, and only need to arrange the conduction wires 403 according to the current usage, which will not be described here in detail. Instead of using the composite column insulator 421, the jumper device 420 can use other forms of insulation members to connect the jumper wire 402 as long as it can meet the actual usage requirements.

[053] As shown in Figure 8, an elongated member 412 is also connected to the end connecting member 411. In the horizontal projection, the elongated member 412 extends outwardly from the end connecting member 411. Two lead wires 403 on both sides of the tower body are respectively connected to both ends of the elongated member 412. In this example, the elongated member 412 is arranged horizontally on the end connecting member 411 and perpendicular to the composite column insulator 421. The angle between the elongated member 412 and the center line of the transverse arm 410 is greater than the angle between the lead wire 403 and the center line of the transverse arm 410.

[054] In this example, the angle between the conduction wire 403 and the center line of the transverse arm 410 is 60 degrees, and the angle between the elongated member 412 and the center line of the transverse arm 410 is 90 degrees. The arrangement of the elongated member 412 should be equivalent to extending the virtual intersection of the two corner lead wires 403 on the same side of the tower body 401. Thus, the distance from the lead wire 403 to the tower body 401 is increased. The electrical gap between the lead wire 403 and the tower body 401 is satisfied without changing the length of the cross arm 410, and the cross arm 410 is prevented from being excessively long.

[055] In this example, the elongated member 412 is arranged horizontally on the end connecting member 411, so that the angle between the elongated member 412 and the center line of the transverse arm 410 can be directly compared. However, it is obvious that the elongated limb may not be completely in the horizontal plane either. The elongated member 412 may be displaced by an angle in the vertical plane, provided that in the horizontal projection, the angle between the elongated member 412 and the center line of the transverse arm 410 is greater than the angle between the lead wire 403 on the same side and on the centerline of the cross arm 410.

[056] In this example, one end of the end connecting member 411 is a sleeve connected to the cross arm 410. Another end of the end connecting member 411 is a connecting plate (not shown), which is connected and fixed to the member elongated member 412. The end connecting member 411 may include any suitable connecting member, i.e., that can be attached to the elongated member 412 as known to one skilled in the art, which will not be described in detail here. Furthermore, the lead wire 403 can be connected to the elongated member 412 by any suitable connecting means known to the person skilled in the art, for example, by being secured through a wire clamp.

Example Five

[057] As shown in Figure 9, the voltage tower 500 in this example is substantially the same as the voltage tower 400 in Example Four Four, except that the jumper wire 502 is suspended to a composite column insulator 521 through a connection fitting 530.

[058] Specifically, as shown in figure 10, the flange 522 at the end of the composite column insulator 521 is provided with a connection hole 523, through which the connection fitting 530 is connected. At least two wire clamps 531 are disposed in the connection socket 530, and at least two wire ties 531 can secure the jumper wire 502. In this example, the wire clamps 531 and the connection socket 530 may not adopt any existing configurations. appropriate, as long as the connection can be made, which will not be described in detail here.

[059] An adjusting member 532 may also be arranged between the connecting fitting 530 and the flange 522 to adjust the distance between the connecting fitting 530 and the composite column insulator 521 to meet the requirements of different operating conditions. The adjusting member 532 is a strip-shaped plate, and a plurality of spaced through holes are arranged along the longitudinal direction of the adjusting member 532. The distance between the connecting fitting 530 and the composite column insulator 521 can be adjusted by connecting the connecting fitting 530 to different through holes in the adjusting member 532. Of course, the adjusting member 532 can take other forms. For example, an end portion of one of the adjusting member 532 and the connecting fitting 530 may be provided with a threaded rod, and another end portion may be provided with a thread that cooperates with the threaded rod. The threaded rod can be screwed into the thread, and the screwing length can be adjusted, so that the distance between the connecting fitting and the composite column insulator can be adjusted by screwing the threaded rod into the thread by different lengths.

Example Six

[060] As shown in Figure 11 and Figure 12, in this example, the tension tower 600 in this example is substantially the same as the tension tower 400 in Example Four, except for the fact that the transverse arm 610 is a transverse arm composed of V shape. The opening of the V-shaped composite cross-arm is connected to the tower body 601, and the V-shaped composite cross-arm includes an end connecting member 611, the elongated members 612 and a jumper device 620 at the apex of the V shape. The elongated members 612 are respectively arranged on both sides of the end connecting member 611, and the jumper device 620 is arranged horizontally on the end connecting member 611.

[061] The cross-arm 610 includes two cross-arm composite insulators 613. Each cross-arm composite insulator 613 includes an insulation tube 614 and silicone rubber coating 615 outside the insulation tube 614. The insulation tube 614 can be filled with insulating gas such as S6, or can be filled with polyurethane foam. The two cross-arm composite insulators 613 are fixedly connected together at the apex of the V-shape by the end connecting member 611.

[062] Two elongated members 612 are arranged on both sides of the end connecting member 611 respectively, and the two leading wires 603 at the corner are respectively suspended on the two elongated members 612. In this example, the angle between the leading wire 603 and the center line of the transverse arm 610 is 50 degrees, and the angle between the elongated member 612 and the center line of the transverse arm 610 is 70 degrees. The arrangement of the elongated member 612 is equivalent to extending the virtual intersection of the two corner lead wires 603 on the same side of the tower body 601, so that the distance from the lead wire 603 connected to the transverse arm 610 suspended by the member lengthened 611 to turret body 601 is increased. The cross arm 610 is prevented from being excessively long under the condition of meeting electrical insulation distance requirements.

[063] Furthermore, two reinforcing members are arranged at the free end of the transverse arm 610. The two reinforcing members include inclined members 616 and auxiliary members 617. The inclined member 616 and the elongated member 612 form the V-shaped structure That is, the end parts of the inclined member 616 and the elongated member 612 are fixed to the connecting plate 618 to form a V-shaped apex. The other end of the inclined member 616 is fixed to the end connecting member 611. Arrangement of the inclined member 616 increases the rigidity and strength of the elongated member 612. The auxiliary member 617 is connected to the inclined member 616 and the elongated member 612, thus the V-shaped structure formed by the inclined member 616 and the elongated member 612 is reinforced, that is, to further increase the rigidity and strength of the elongated member 612.

[064] Due to the use of the elongated member 612, the transverse arm 610 is prevented from being excessively long, so that the tension tower 600 provided with the transverse arm 610 can avoid the situation in which the requirement on electrical clearance between the wire conduction 603 and tension tower 600 is not satisfied. The tension tower is light and the line corridor is narrow. Furthermore, the number of corner lead wires 603 can be any suitable number, and the corner lead wires 603 can also be coiled lead wires.

[065] It will be understood by those skilled in the art that the transverse arms on the angle towers described in Examples One to Three can be applied to tension towers and, similarly, the transverse arms on the tension towers described in Examples Three to Six can also be applied. be applied to angle towers.

[066] The modalities described above represent only different modalities of the present disclosure, the description of which is more specific and detailed. But it should not be construed as limiting the scope of the present patent. It should be noted that, for those skilled in the art, various modifications and improvements may be made without departing from the concept of the present disclosure, which may also fall within the scope of protection of the present disclosure. Therefore, the scope of the disclosure must be determined by the appended claims.

Claims (19)

1. Transverse arm (110, 310, 410, 610) applied to an angle tower (100, 300) comprising a tower body (101, 301, 401, 601), an end of said transverse arm (110, 310, 410, 610) being connected to said tower body (101, 301, 401, 601), the other end of said transverse arm (110, 310, 410, 610) distant from said tower body (101, 301, 401, 601) being a free end for connecting a conduction wire (103, 203, 303, 403, 603), CHARACTERIZED by the fact that: said free end comprises an end connecting member (111, 211, 311, 411, 611) and an elongated member (112, 212, 312, 412, 612) attached to said end connecting member (111, 211, 311, 411, 611), and said elongated member (112, 212, 312, 412, 612) is placed in a horizontal plane or displaced by an angle in the vertical plane; in a horizontal projection, said elongated member (112, 212, 312, 412, 612) extends outwardly from said end connecting member (111, 211, 311, 411, 611); said conduction wire (103, 203, 303, 403, 603) is connected to said elongated member (112, 212, 312, 412, 612); and an angle between said elongated member (112, 212, 312, 412, 612) and a center line of said transverse arm (110, 310, 410, 610) is greater than an angle between said conduction wire (103, 203, 303, 403, 603) and said center line of said transverse arm (110, 310, 410, 610). 2. Transverse arm (110, 310, 410, 610), according to claim 1, CHARACTERIZED by the fact that said elongated member (112, 212, 312, 412, 612) is disposed on both sides of said member end connection connector (111, 211, 311, 411, 611). 3. Transverse arm (110, 310, 410, 610), according to claim 1, CHARACTERIZED by the fact that an elongated member (112, 212, 312, 412, 612) is disposed on said end connecting member ( 111, 211, 311, 411, 611), and two lead wires at a corner are connected to both ends of said elongated member (112, 212, 312, 412, 612) respectively. 4. Transverse arm (110, 310, 410, 610), according to claim 1, CHARACTERIZED by the fact that said elongated member (212) is joined by a plurality of support segments (219). 5. Transverse arm (110, 310, 410, 610), according to claim 1, CHARACTERIZED by the fact that at least one reinforcing member is disposed on said elongated member (112, 212, 612). 6. Transverse arm (110, 310, 410, 610), according to claim 5, CHARACTERIZED by the fact that said at least one reinforcing member is connected to said elongated member (112, 212, 612) and to the said end connection member (111, 211, 611). 7. Transverse arm (110, 310, 410, 610), according to claim 5, CHARACTERIZED by the fact that at least one auxiliary member (117, 617) is disposed between said reinforcing member and said elongated member ( 112, 212, 612), and said auxiliary member (117, 617) is connected to said reinforcing member and said elongated member (112, 212, 612). 8. Transverse arm (110, 310, 410, 610), according to claim 1, CHARACTERIZED by the fact that said elongated member (112, 212, 312, 412, 612) is disposed in an external corner of said tower angle (100, 300). 9. Transverse arm (110, 310, 410, 610), according to claim 1, CHARACTERIZED by the fact that said transverse arm (110, 310, 410, 610) is a composite transverse arm. 10. Angular tower (100, 300), comprising a tower body (101, 301, 401, 601), CHARACTERIZED by the fact that said angular tower (100, 300) further comprises the transverse arm (110, 310, 410, 610), as defined in any one of claims 1 to 9. 11. Transverse arm (110, 310, 410, 610) applied to a tension tower (400, 500, 600) comprising a tower body (401, 601), an end of said transverse arm (110, 310, 410 , 610) being connected to said tower body (401, 601), and the other end of said transverse arm (110, 310, 410, 610) distant from the tower body (401, 601) being a free end for connecting a conduction wire (103, 203, 303, 403, 603), CHARACTERIZED by the fact that said free end is provided with an end connection member (111, 211, 311, 411, 611), and a jumper device ( 120, 420, 620) disposed horizontally on said end connection member (111, 211, 311, 411, 611) and configured to be suspended with a jumper wire (402, 502); said tension tower (400, 500, 600) is an angular tower (100, 300); said end connecting member (111, 211, 311, 411, 611) is further connected to an elongated member (112, 212, 312, 412, 612), and said elongated member (112, 212, 312, 412, 612) is placed in a horizontal plane or displaced by an angle in the vertical plane; in a horizontal projection, said elongated member (112, 212, 312, 412, 612) extends outward from said end connecting member (111, 211, 311, 411, 611); said conduction wire (103, 203, 303, 403, 603) is connected to said elongated member (112, 212, 312, 412, 612); and an angle between said elongated member (112, 212, 312, 412, 612) and a centerline of said transverse arm (110, 310, 410, 610) is greater than an angle between said conduction wire ( 103, 203, 303, 403, 603) and said center line of said transverse arm (110, 310, 410, 610). 12. Transverse arm (110, 310, 410, 610), according to claim 11, CHARACTERIZED by the fact that said jumper device (120, 420, 620) is a composite column insulator (421, 521), a one end of said composite column insulator (421, 521) is connected to said end connecting member (111, 211, 311, 411, 611), and the other end of said composite column insulator (421, 521) is suspended with said jumper wire (402, 502). 13. Transverse arm (110, 310, 410, 610), according to claim 12, CHARACTERIZED by the fact that said composite column insulator (421, 521) is suspended with said jumper wire (402, 502) by a connection fitting. 14. Transverse arm (110, 310, 410, 610), according to claim 11, CHARACTERIZED by the fact that said elongated member (112, 212, 312, 412, 612) is disposed on both sides of said member end connection connector (111, 211, 311, 411, 611). 15. Transverse arm (110, 310, 410, 610), according to claim 11, CHARACTERIZED by the fact that an elongated member (112, 212, 312, 412, 612) is disposed on said end connecting member ( 111, 211, 311, 411, 611), and two lead wires on both sides of said tower body (401, 601) are respectively connected to both ends of said elongated member (112, 212, 312, 412, 612). 16. Transverse arm (110, 310, 410, 610), according to claim 11, CHARACTERIZED by the fact that at least one reinforcing member is disposed on said elongated member (112, 212, 612). 17. Transverse arm (110, 310, 410, 610), according to claim 16, CHARACTERIZED by the fact that said at least one reinforcing member is connected to said elongated member (112, 212, 612) and the said end connection member (111, 211, 611). 18. Transverse arm (110, 310, 410, 610), according to claim 11, CHARACTERIZED by the fact that said transverse arm (110, 310, 410, 610) is a transverse arm (110, 310, 410, 610) compound. 19. Tension tower (400, 500, 600) comprising a tower body (101, 301, 401, 601), CHARACTERIZED by the fact that said tension tower (400, 500, 600) further comprises said arm transversal (110, 310, 410, 610), as defined in any one of claims 11 to 18.