RU61762U1 - SUPPORT FOR ANTENNA-FEEDER SYSTEM - Google Patents

Abstract

The utility model relates to the field of radio communications and can be used as a support for mounting an antenna-feeder system (hereinafter - AFS) of cellular communication stations.

The utility model solves the problem of creating a sectional structure of a support for mounting an AFS, characterized by a reduced mass, low laboriousness of manufacture, and also increased convenience of delivery and installation.

This problem is solved in a design that includes sections interconnected by means of flange connections.

The problem is solved in that the sections are made of steel pipes, and the pipe diameter of the lower section is larger than the diameter of the pipe of the higher section, the section flanges are made of steel and equipped with welded stiffeners, and the lower flange of each higher section is equipped with a discharge ring connected to the stiffeners. In this case, the support can be made of three sections, the outer diameters of the pipes of which are 630, 426 and 273 mm, respectively, and the length of the sections is 11.5 m, 7.5 m and 9 m, respectively. The lower section of the support can be equipped with a protective visor that excludes damage by icicles lower cables AFS. 1 n., 2 wp f-ly, 3 ill.

Description

The utility model relates to the field of radio communications and can be used as a support for mounting an antenna-feeder system (hereinafter - AFS) of cellular communication stations.

The prior art telescopic support for mounting AFS, see patent for utility model RU39156U1, IPC E 04 H 12/18, publ. July 20, 2004, bull. RU BIPM No. 20, including elbows made of pipe sections and connected by key connections, and extensions.

The disadvantages of such a support are the increased complexity of the design, the high complexity of manufacturing, a significant area occupied by the support, and low height.

Also known is a support for mounting an AFS (see the journal “Technologies and means of communication.” No. 2 (29) / 2002, p. 41), made in the form of a monolithic reinforced concrete barrel of variable cross-section.

The design flaws are significant dimensions and weight, which make delivery and installation of the support difficult in a city with a high density of buildings and structures.

For the prototype of the claimed utility model, the support structure for attaching the APS is taken, see patent for utility model RU37749U1, IPC E 04 H 12/08, publ. 05/10/2004, bull. RU BIPM No. 13, which includes truncated pyramidal sections interconnected by means of flange joints, each of which is made of belts connected by ties.

The disadvantages of the prototype are the increased complexity of the design and the high complexity of manufacturing.

The objective of the claimed utility model is the creation of a sectional structure of the support for mounting the APS, characterized by reduced weight, low manufacturing complexity, as well as increased ease of delivery and installation.

This problem is solved in a design that includes sections interconnected by means of flange connections.

The problem is solved in that the sections are made of steel pipes, and the pipe diameter of the lower section is larger than the diameter of the pipe of the higher section, the section flanges are made of steel and equipped with welded stiffeners, and the lower flange of the higher section is equipped with a discharge ring connected to the stiffeners. In this case, the support can be made of three sections, the outer diameters of the pipes of which are 630, 426 and 273 mm, respectively, and the length of the sections is 11.5 m, 7.5 m and 9 m, respectively. The lower section of the support can be equipped with a protective visor that excludes damage by icicles lower cables AFS.

The utility model is illustrated by the following drawings.

Figure 1 shows the support, a General view.

Figure 2 shows the section of the support.

Figure 3 shows the construction of the lower flange of the section in section.

The claimed technical solution can be implemented as follows.

The support (see Figure 1) is performed by a team of sections 1, 2, 3. For the manufacture of sections, pieces of steel pipes of various sections are used.

The articulation of the sections is carried out by means of flange connections.

To the ends of each section (see Figure 2), the lower 4 and upper 5 flanges are welded in the form of rings of sheet steel.

Flanges 4, 5 are reinforced with stiffening ribs 6, also made of sheet steel and welded to the surface of the flange and the surface of the pipe section.

To enhance the rigidity of the structure, the stiffening ribs 6 of the lower flange 4 of each higher section of the support are connected by welding with a discharge ring 7 of sheet steel.

The sections are equipped with welded ladder brackets 8. In the manufacturing variant (not shown in FIG.), The support sections can be provided with segments of the stairs, and the ladder can be equipped with a safety cage, which excludes the possibility of falling personnel.

The upper section of the support is equipped with a lightning rod. In an embodiment (not shown in FIG.), The upper section may be provided with a pad; in this case, a lightning rod is installed at one end of the pad.

After sections are made, a protective layer of paint is applied to the outer surfaces of the product. Antennas are installed on the upper sections, and AFS cables are attached to the side sections of the brackets.

The lower section can be equipped with a protective visor 9 (see Figure 1), eliminating damage by icicles of cable reduction. Visor 9

represents a piece of steel sheet connected to the pipe surface of the lower support section.

Due to the use of sections with different cross sections, decreasing to the top of the support, there is no need to use stretch marks, thereby reducing the area occupied by the support.

Using as a material for the manufacture of sections of the support of pipes of large diameter the mass of the claimed support is significantly lower than the weight of the supports having a different design, subject to the equality of heights of the compared supports.

The use of a limited range of parts and materials can significantly reduce the complexity of manufacturing the support and its cost.

Sections deliver to the place of construction of the support in road transport. Due to the small size and weight of the sections, the delivery of sections to inaccessible places and the installation of the support are greatly simplified.

The end of the lower section of the support is buried in the ground. To seal a support into the ground, a typical design is used for reinforced concrete supports of a similar purpose.

In an embodiment of a support 25 m high (above ground level), developed in accordance with applicable state norms, rules and standards, and successfully implemented by the applicant, three sections were used, made of steel pipes with external diameters of 630, 426 and 273 mm, respectively. The length of the sections was 11.5 m, 7.5 m and 9 m. The lower support is buried in the ground by 3 m. On such a support

simultaneous installation of a parabolic antenna with a diameter of 0.6 m (at a height of 25 m above the ground) and six panel antennas of 3 pieces at a height of 17.5 m and 21 m (above the ground) is possible. The weight of the support is two times less than the weight of the 25-meter reinforced concrete support, traditionally used to mount the AFS of cellular communication stations.

Claims (3)

1. Support for the antenna-feeder system, including sections interconnected by means of flange connections, characterized in that the sections are made of steel pipes, the pipe diameter of the lower section being larger than the diameter of the pipe of the higher section, the flanges of the sections are made of steel and equipped welded stiffeners, and the lower flange of the higher section is equipped with a discharge ring connected to stiffeners. 2. The support according to claim 1, characterized in that it is made of three sections, the outer diameters of the pipes of which are 630, 426 and 273 mm, respectively, and the length of the sections is 11.5, 7.5 and 9 m, respectively. 3. A support according to any one of claims 1, 2, characterized in that the lower section of the support is equipped with a protective visor that prevents icicles from damaging the cables of the APS.