RU95173U1 - INSULATING CROSS - Google Patents

Abstract

 1. An insulating traverse containing a support and suspension insulators, one ends of which are pivotally mounted on the support at a distance from each other, and the second ends are connected to each other and to the phase wire of the power line, characterized in that both insulators are mounted on the support at an acute angle, forming an acute-angled triangle with the support section. ! 2. Traverse according to claim 1, characterized in that the ends of the insulators are interconnected by means of a linear connector. ! 3. Traverse according to claim 1, characterized in that the ends of the insulators are interconnected by means of a plate insulator. ! 4. Traverse according to claim 1, characterized in that a linear type surge suppressor OPN-P-PI is used as a suspension insulator. ! 5. The traverse according to claim 1, characterized in that the hinge assemblies are fixed to the support using the adapter plate.

Description

The utility model relates to electrical engineering, namely to high-voltage power lines, and can be used in the construction of insulating traverses designed to suspend the phase conductors of the lines to the supports.

Known designs of insulating traverses using commercially available insulators, both porcelain and polymer. See, for example, “Energy Construction Abroad,” 1978, No. 5, pp. 37-46.

Also known are the designs of insulating traverses, consisting of three rod insulators, fixed in the form of three beams through metal ends to the top of the support strut. At the free ends of the insulators, current-carrying phase wires of a high-voltage power line are fixed. (RF patent 2159969, class Н01В 17/02 publ. 11/27/2000). The principal drawback of these structures is the excess of permissible loads on the insulation elements used in them. The support and rod insulators used in them have significant limitations on the allowable bending forces directed perpendicular to the axis of the insulator. In the above constructions, the load from the gravity of the wires acts in the perpendicular direction relative to the axis of the insulator, which limits the use of supporting-rod insulators as insulating structures according to mechanical characteristics.

Closest to the proposed solution is the design of an insulating crosshead for hanging wires on a power line support, made of a combination of suspended (linear) and support rod insulators. (RU patent on ПМ №52250 dated 2006.). In this design, the insulators are mounted on a support at a distance from each other, at the point of attachment of the wire are combined in a common attachment point, thereby forming a rectangular triangle, one side of which is the portion of the support located between the attachment points of the support and suspension insulators, and the other two sides are reference and suspension insulators. In this case, the suspension insulator is located horizontally, and the support is downward from the connecting node to the support at an acute angle. The attachment points of the insulators to the support are hinged and allow the traverse to rotate up to 90 ° around an axis parallel to the axis of the support. The insulators are attached to the support with a metal clamp. A polymeric rod insulator is used as a suspended (linear) insulator, and a polymeric rod and core insulator is used as a reference.

The specified design of the traverse also has several disadvantages. The hinged fastening of the insulators to the support and the horizontal location of the suspension insulator leads to the fact that the gravity of the wire, as well as ice and wind loads, act on the suspension insulator in tension, and in relation to the reference insulator in compression. The decomposition of the action of gravity Ft into components in this case is shown in figure 1. The tensile force F _{Rast of the} suspension insulator 1 and the compression force F _{Cg of the} support insulator 2 with the horizontal location of the suspension insulator are determined by the following formulas:

From formulas (1.1) it can be seen that with a horizontal arrangement of a linear suspension insulator at any angle B greater than 0 degrees, the compressive force for the reference insulator exceeds the load from the weight of the wires. At angles B less than 45 °, the tensile force is less than the gravity of the wire, and at angles greater than 45 ° degrees, the tensile force for the linear suspension insulator exceeds the load from the gravity of the wires. At an angle of 45 °, the compression load of the support insulator will be 41.4% more than the load from the weight of the wire. At the same time, a torque occurs on the support section between the attachment points of the insulators, affecting the support body, exceeding the force from the gravity of the wires. Such operating conditions reduce the reliability of the design and can lead to damage to the insulators and wire breakage.

Polymeric insulators, supporting and suspended, are made on the basis of fiberglass rods, which carry a mechanical load in insulating structures. According to GOST 27380-87 "Fiberglass profile electrical insulating", the tensile strength is at least 900 MPa, and the compressive strength is at least 260 MPa. This shows that polymer insulators based on fiberglass rods work most effectively in tension. Thus, when using such an insulating crosshead, it is necessary to take into account the distance to the attachment point of the support insulator and take into account the excess compression load, which limits its use for fastening wires with different weights and for various icy-wind loads.

The proposed solution to the design of the insulating beam increases the reliability of the insulating beam with polymer insulators.

The problem is solved as follows. In an insulating traverse containing support and suspension insulators, one end of which is pivotally mounted on a support at a distance from each other, and the second ends are connected to each other and to a wire, both insulators are fixed to the support at an acute angle, forming an acute-angled triangle with the support section.

The ends of the insulators can be interconnected by means of a linear connector or a plate insulator.

As a suspension insulator, a surge suppressor of the linear type OPN-P-PI can be used.

The hinge assemblies can be secured to the support using an adapter plate.

In the proposed design, the tensile force of the suspension insulator will be greater than the gravity of the wires, and the compression force for the reference insulator will be less than the gravity of the wire, which leads to an increase in the reliability of the insulators.

The proposed insulating traverse is shown in figure 2.

The insulating crosshead consists of a suspension insulator 1, a supporting insulator 2, a node for their connection 3, which provides for the possibility of fixing a wire in it, and nodes 4 and 5 for attaching each of the insulators to the support 6. In this case, the suspension insulator 1 is attached to the support at an acute angle above the point connection of insulators 3, and the supporting insulator is attached to the support below the connecting node 3 at an acute angle.

A rod-type linear polymer insulator is used as a linear insulator 1, and a rod-shaped polymer insulator as a reference insulator 2. A suspended wire or an intermediate ceramic plate insulator is fixed to the node 3 of the connection of insulators using standard linear connectors, which can be used to reduce electrical voltage on the head ends of polymer insulators.

To remove the transverse loads on the insulators that may occur when the wire is broken, the nodes 4 and 5 of the fastening of the insulators to the support 6 are made hinged. This will ensure that the entire suspension rotates around a vertical axis (parallel to the axis of the support), up to an angle close to 90 °. In this case, in the event of a longitudinal tensile force, the insulating crosshead essentially passes from the support suspension mode to the anchor suspension mode, and thereby prevents the wire from falling to the ground throughout the section to the next anchor support.

The hinge nodes 4 and 5 are fixed to the support 6 using the adapter plate.

The decomposition of the action of gravity Ft into components in this case is shown in Fig.3. The force F a tensile _Rast suspension insulator 1 and the compression force F _Cx support insulator 2 at an arbitrary angle insulators location determined by the following formulas:

From the formulas (2.1) it can be seen that when the insulators are located at an angle to the support and when the condition is fulfilled, the angle A = 180 ° -2 × B, the tensile force for the suspension insulator will be equal to the gravity of the wire. The compression force for the supporting insulator in this case, at angles A greater than 60 °, will be less than the gravity of the wires. This improves the reliability of the traverse. In addition, this will simplify the choice of linear suspension insulators according to the criterion of normalized tensile tensile strength, and when choosing a reference insulator - according to the criterion of gravity of a current-carrying wire.

With an increase in the angle of attachment of the support insulator 2 to the support (horizontal or close to horizontal, when the angle B is approximately 90 °), the tensile and compression forces are equal to:

In this case, the tensile force of the suspension insulator will be greater than the gravity of the wires, and the compression force for the supporting insulator at angles A, less than 45 °, will be less than the gravity of the wire, which leads to more reliable operation of the suspension insulator operating in tension.

In this design, the traverse as a suspension insulator 1 can be used suspended polymer surge suppressor linear type OPN-P-PI. The use in the construction of fiberglass materials similar to those used in suspended polymer rod insulators provides OPN-P-PI with high mechanical tensile strength. The presence of non-linear varistors inside the design of the arrester allows you to limit the effect of overvoltage, which reduces the insulation distance between the wire and the support and allows you to reduce the height of the support and the linear dimensions of the insulators.

Sources of information taken into account when drawing up an application for a utility model:

1. RF patent 2159969, class НВВ 17/02, publ. 11/27/2000;

2. The journal "Energy construction abroad" 1978, No. 5, pp. 37-46

3. Patent RU 52250 U1 H01B 17/02, publ. 03/10/2006).

Claims (5)

1. An insulating traverse containing a support and suspension insulators, one ends of which are pivotally mounted on the support at a distance from each other, and the second ends are connected to each other and to the phase wire of the power line, characterized in that both insulators are mounted on the support at an acute angle, forming an acute-angled triangle with the support section. 2. Traverse according to claim 1, characterized in that the ends of the insulators are interconnected by means of a linear connector. 3. Traverse according to claim 1, characterized in that the ends of the insulators are interconnected by means of a plate insulator. 4. Traverse according to claim 1, characterized in that a linear type surge suppressor OPN-P-PI is used as a suspension insulator. 5. The traverse according to claim 1, characterized in that the hinge assemblies are fixed to the support using the adapter plate.