KR102196715B1 - Connection structure of different plate for transmission line joint point - Google Patents

Abstract

The connection structure of the transmission line wire connection point dissimilar plate of the present invention prevents the penetration of external foreign substances and overheating by enclosing the connection surface plate on the compression clamp side of the transmission line with the contact point of the jumper terminal on the jumper line side. As a result, it is possible to eliminate the inconvenience and hassle of having to check the contact point or check the penetration of foreign substances through air inspection at the same time and eliminate excessive inspection costs.

Description

Transmission line connection structure of dissimilar plates {CONNECTION STRUCTURE OF DIFFERENT PLATE FOR TRANSMISSION LINE JOINT POINT}

The present invention relates to a connection structure of a dissimilar plate at a power transmission line, and more particularly, to a connection structure of a dissimilar plate at a power transmission line with an improved contact point between a compression clamp side connection face plate of a transmission line and a jumper terminal at a jumper line. .

In general, when constructing a transmission line that supplies electricity, a number of compression clamps are installed at the tip of the transmission line in order to maintain the tension of the transmission line. The compression clamp supports the tip of the transmission line and simultaneously It is a device that preserves the condition of the connection part well.

The compression clamp is manufactured as a highly conductive high-purity aluminum (Al) material so as to maintain durability against vibrations caused by the weight and wind pressure of the power transmission line itself, and transmit high-quality electricity.

1 and 2, the compression clamp 10 for fixing a transmission line according to the prior art is not shown in combination with the core 1a of the transmission line 1 (a state in which a part of an aluminum element is peeled off). A core coupling portion 2 formed to be compressed and fixed by a hydraulic compressor (a compression force of about 100 tons is applied in the radial direction), an uneven portion 3 formed on the upper portion of the core coupling portion 2, and A steel clamp (5) consisting of a connection ring (4) formed by maintaining a certain distance from the uneven portion (3), and is crimped and fixed to the outer surface of the steel clamp (5), and surrounds a part of the transmission line (1) It includes a pipe body 6 securing a certain length to be supported.

That is, the compression clamp 10 is installed so as to support and fix the end of the electric wire in which the catenary angle of the transmission line 1 is embossed in the pylon 7 of the transmission station, and the steel clamp at the lower part of the compression clamp 10 A jumper terminal 9 is connected to the contact surface plate 11 coupled to (5) by connecting the jumper wire 8 with the power transmission line 1 to make it conductive.

However, the conventional contact surface plate 11 and the jumper terminal 9 configured therein are a plurality of bolts 12, nuts 13, and washers passing through these contact points in a state where the contact points are in direct contact with each other so that they are in surface contact. It is a structure that is fastened by a fastening means consisting of (14), but this surface contact structure is overheated when external foreign matter penetrates due to external exposure of the entire contact point in direct contact, so the worker climbs up to the pylon 7 of the power transmission station. There was a problem that not only the inconvenience and hassle of having to check contact points or check the penetration of foreign substances through air inspections from time to time, but also excessive inspection costs were incurred.

Korean Patent Publication No. 10-0882506 (2009.02.02)

An object of the present invention has been proposed to solve the problems in view of the existing problems, and prevents overheating due to penetration of external foreign substances between the contact points of the connection face plate on the compression clamp side of the transmission line and the jumper terminal on the jumper line side. The purpose is to provide a connection structure of a disparate plate of a transmission line wire connection point that can increase the conductive efficiency by increasing the contact area.

A transmission line wire connection point disparate plate connection structure according to an embodiment of the present invention for solving the above technical problem includes a contact surface plate installed between the steel clamp on the compression clamp side and the pipe body, and a jumper terminal installed on the jumper wire. , A dissimilar plate of copper alloy inserted between the contact points of the contact surface plate and the contact points of the jumper terminals and simultaneously surrounds the ends and both sides of these contact surface plates and jumper terminals, and the contact surface plate and the jumper terminal and dissimilar plates are simultaneously fastened. Including a fastening means consisting of a plurality of bolts and nuts and washers to,
The heterogeneous plate is formed to be symmetrical back and forth between the contact surface plate and the inner surface of the contact point on the jumper terminal side, and a central surface portion interposed therebetween so as to be in simultaneous surface contact with the inner surface of the contact point on the jumper terminal side, while being integrally formed to be wider than the thickness of the central surface portion. A pair of left and right side surfaces that are formed to extend and wrap so as to be in surface contact with both sides of the contact surface plate and the contact points on the jumper terminal side, and the upper and lower limits that surround the contact surface plate and the end surfaces of the contact points on the jumper terminal side. A plurality of fastening holes formed to coincide with the fastening holes formed in the contact surface plate and the jumper terminal for the top and bottom and left and right of the pair of end faces, and the left and right pair of both side faces and a pair of top and bottom When the contact points on both sides of the contact surface plate and the jumper terminal are in close contact with each other with the dissimilar plate therebetween, the fastening holes formed in the contact points of the contact surface plate and the jumper terminal and the fastening holes formed in the dissimilar plate are automatically matched. It is characterized by being formed.

delete

delete

delete

delete

The connection structure of the transmission line wire connection point dissimilar plate of the present invention prevents the penetration of external foreign substances and overheating by enclosing the connection surface plate on the compression clamp side of the transmission line with the contact point of the jumper terminal on the jumper line side. Due to this, there is an effect of eliminating the inconvenience and hassle of having to check the contact point or check the penetration of foreign substances through aerial inspection at the same time, and at the same time eliminating excessive inspection costs.

In addition, the connection structure of the dissimilar plate at the power transmission line connection point of the present invention is the connection part due to the gap between the bolts when the contact surface plate and the jumper terminal are fastened by a fastening means consisting of a plurality of bolts, nuts and washers via the dissimilar plate. In addition to minimizing construction difficulties and work delays such as inconsistencies, there is an effect of dispersing the compressive force due to the use of a disparate plate having a size larger than that of general washers.

In addition, since the connection structure of the dissimilar plate of the transmission line wire connection point of the present invention can strengthen the elastic force due to the use of the dissimilar plate of copper alloy, the bonding strength is improved compared to the contact surface plate and jumper terminal made of the existing aluminum alloy. At the same time, there is an effect of increasing the conductive efficiency by increasing the contact area.

1 is a perspective view showing a connection structure of contact points between a compression clamp side connection surface plate of a transmission line and a jumper terminal side of a jumper line according to the related art;
FIG. 2 is a side view showing a contact point connection structure between a compression clamp-side connection surface plate of a transmission line and a jumper terminal on a jumper line according to the related art;
3 is an exploded perspective view showing a connection structure between a compression clamp side connection surface plate and a jumper line side jumper terminal of a transmission line according to the present invention;
4 is a combined longitudinal sectional view showing the contact point connection structure between the compression clamp side connection surface plate of the power transmission line and the jumper line side jumper terminal according to the present invention;
5 is a cross-sectional view taken along line AA of FIG. 4.

In order to fully understand the present invention, preferred embodiments of the present invention will be described with reference to the accompanying drawings. The embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. This embodiment is provided to more completely explain the present invention to those of ordinary skill in the art. Therefore, the shape of the element in the drawings may be exaggerated to emphasize a clearer description. It should be noted that in each drawing, the same configuration may be indicated by the same reference numeral. Detailed descriptions of known functions and configurations that are determined to unnecessarily obscure the subject matter of the present invention will be omitted.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

3 is an exploded perspective view showing the connection structure between the compression clamp side connection surface plate of the power transmission line and the jumper line side jumper terminal according to the present invention, and FIG. 4 is a contact between the compression clamp side connection surface plate of the transmission line and the jumper line side jumper terminal according to the present invention. It is a combined longitudinal sectional view showing the connection structure at the point, and Fig. 5 is a cross-sectional view taken along line AA of Fig. 4.

For the configuration of the present invention, the same reference numerals and names as those of the conventional configuration are assigned the same, and duplicate descriptions thereof are omitted.

3 to 5, the connection structure of the dissimilar plate at the power transmission line connection point according to the embodiment of the present invention is a contact surface installed between the compression clamp 10 side steel clamp 5 and the pipe body 6 It is inserted between the plate 11, the jumper terminal 9 installed on the jumper wire 8, and the contact points between the contact surface plate 11 and the jumper terminal 9, and these contact surface plates 11 and jumper terminals ( A plurality of bolts 12 and nuts 13 simultaneously fastening the disparate plate 30 that simultaneously surrounds the ends of 9) and both sides of the contact surface plate 11 and the jumper terminals 9 and the disparate plate 30 And it includes a fastening means made of a washer (14).

At this time, the dissimilar plate 30 is made of a copper alloy, and the central surface portion 31 interposed therebetween so as to be in simultaneous surface contact with the inner surface of the contact point of the contact surface plate 11 and the jumper terminal 9 side. ), and a pair of left and right side surfaces that are formed symmetrically on both sides with the central surface part 31 interposed therebetween, and wrap them in surface contact with both sides of the contact points on the contact surface plate 11 and the jumper terminal 9 side ( 32), and a pair of upper and lower end face portions 33 that surround each end face of the contact point on the contact surface side of the contact surface plate 11 and the jumper terminal 9, and the upper and lower and left and right sides of the central face portion 31 Consists of a plurality of fastening holes 34 formed to match the fastening holes 11a and 9a formed in the contact surface plate 11 and the jumper terminal 9 for the contact surface plate 11 and the jumper terminal 9.

That is, the pair of left and right side surfaces 32 are formed to be symmetrical back and forth with the central surface part 31 interposed therebetween, and are integrally formed to extend wider than the thickness of the central surface part 31 so that the contact points on the contact surface plate 11 Both side surfaces and both side surfaces of the contact points on the jumper terminal 9 side are wrapped so as to be in surface contact.

The upper and lower ends of the pair of end portions 33 are formed in a diagonal direction in which the upper side and the lower side deviate from each other with respect to the central surface portion 31, so that the end of the contact point on the jumper terminal 9 side and the contact surface plate 11 side Each end of the contact point is wrapped so that it is in surface contact.

At this time, the left and right pair of both side surfaces 32 and the upper and lower pair of both side surfaces 33 are in close contact between the contact surface plate 11 and the jumper terminal 9 with the disparate plate 30 interposed therebetween. When abutting, the fastening holes 11a and 9a formed in the contact points of the contact surface plate 11 and the jumper terminal 9 and the fastening holes 34 formed in the disparate plate 30 are automatically formed at the same position. Therefore, when the contact surface plate 11, the dissimilar plate 30, and the jumper terminal 9 are simultaneously fastened by a fastening means consisting of a plurality of bolts 12, nuts 13, and washers 14, the fastening hole 11a In addition to eliminating the inconvenience and hassle of having to match each of the (9a) (34), it is possible to minimize construction difficulties and work delays such as inconsistency of connection parts due to gaps between multiple bolts 12.

In particular, the contact point between the contact surface plate 11 and the jumper terminal 9 is twisted or opened by a pair of left and right side portions 32 of the disparate plate 30 and a pair of upper and lower end portions 33. It can be prevented in advance.

In addition, when the dissimilar plate 30 is interposed between the contact points of the contact surface plate 11 on the compression clamp 10 side of the power transmission line 1 and the contact point of the jumper terminal 9 on the jumper line 8 side, the dissimilar plate ( Since the left and right pair of side portions 32 and the upper and lower pair of end portions 33 of 30) tightly surround both sides and ends of the contact surface plate 11 and the jumper terminal 9 so that they are in surface contact, external foreign matter Since it is possible to prevent overheating due to penetration, it is possible to eliminate the inconvenience and hassle of having to check the contact point or check the penetration of foreign substances through air inspection at any time, as a result of the excessive inspection You can eliminate the cost.

In addition, since the use of the copper alloy dissimilar plate 30 can enhance the elastic force, the bonding strength can be improved compared to the conventional aluminum alloy contact surface plate 11 and the jumper terminal 9. Conductive efficiency can be increased by increasing the contact area.

On the other hand, the present invention is not limited only to the above-described embodiments, but can be carried out with modifications and variations without departing from the gist of the present invention, and the technical idea to which such modifications and modifications are applied also belong to the following claims. Must see.

5: steel clamp 6: pipe body
8: jumper wire 9: jumper terminal
9a: fastening hole 10: compression clamp
11: contact surface plate 11a: fastening hole
12: bolt 13: nut
14: washer 30: different plate
31: central surface portion 32: both side surfaces
33: end portion 34: fastening hole

Claims (5)

A contact surface plate 11 installed between the compression clamp 10 side steel clamp 5 and the pipe body 6,
A jumper terminal (9) installed on the jumper wire (8),
A dissimilar plate 30 made of a copper alloy inserted between the contact points of the contact surface plate 11 and the jumper terminal 9 to simultaneously surround the ends and both sides of the contact surface plate 11 and the jumper terminal 9 and,
Including a fastening means consisting of a plurality of bolts 12 and nuts 13 and washers 14 for simultaneously fastening the contact surface plate 11 and the jumper terminal 9 and the heterogeneous plate 30,
The heterogeneous plate 30,
A central surface portion 31 interposed therebetween so as to be in simultaneous surface contact with the inner surface of the contact surface plate 11 and the contact point of the jumper terminal 9 side;
It is formed to be symmetrical back and forth with the central surface portion 31 interposed therebetween, and is integrally formed to extend wider than the thickness of the central surface portion 31 to make surface contact with both sides of the contact points on the contact surface plate 11 and the jumper terminal 9 side. A pair of left and right sides 32 that surround it so as to be, and
A pair of upper and lower end face portions 33 that surround the contact face plate 11 and the end faces of the contact points of the jumper terminals 9 so as to be in contact with each other,
A plurality of fastening holes 34 formed to coincide with the fastening holes 11a and 9a formed in the contact surface plate 11 and the jumper terminal 9 are configured for the top and bottom and left and right of the central surface part 31,
The left and right pair of both side surfaces 32 and the upper and lower pair of both side surfaces 33 are in close contact with the contact surface plate 11 and the contact point of the jumper terminal 9 with the dissimilar plate 30 interposed therebetween. It is characterized in that the fastening holes (11a) (9a) formed in the contact points on the contact surface plate (11) and the jumper terminal (9) side and the fastening holes (34) formed in the disparate plate (30) are automatically formed at the same position when they touch. Connection structure of dissimilar plates at the wire connection point of the transmission line. delete delete delete delete

Images