RU2670110C1 - THREE-SIDED TRELLISED COLLAPSIBLE TOWER WITH HEIGHT OF UP TO 50 m ON TRANS-SHIPMENTS WITH ADJUSTING FOOT SECTION - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to construction and is intended for use in designs of light collapsible towers up to 50 m high, which do not have a recessed basement and serve for installation at an appropriate height of any equipment. Three-sided trellised collapsible tower with a height of up to 50 m, including several prismatic sections and one foot section, made of welded triangular struts with a constant geometrical scheme, connected to each other on flanges, designed to allow the installation of additional horizontal inserts in order to increase the axial dimension of the foot section.

EFFECT: invention makes it possible to increase the load-carrying capacity and stability of the structures of the towers on trans-shipments, and also ensures an increase in the reliability and durability of structures.

3 cl, 6 dwg

Description

The claimed invention relates to the field of construction and is intended for use in the construction of light collapsible towers up to 50 m high, not having a buried foundation and serving to install at the appropriate height any equipment: radio relay or mobile communications, meteorological, lighting, etc.

Currently, there is a need for light collapsible - mobile - towers of small height up to 50 m, for installation, which do not require an underground foundation.

From the prior art from RU 2305167 C2 (priority from 05/31/2005) a line of collapsible towers is known.

Support belt for a line of metal towers of a collapsible design from 30 to 100 meters high. Each of the towers is a trunk in the form of a spatial lattice truss with inclined and vertical belts of the same length, connected to each other and to the support belt by means of mating elements. Each subsequent tower in height is obtained by removing one inclined or vertical belt from the barrel of the tower. The support belt is made for each of the towers uniform in design and in the number of posts made in the form of identical flat trellised trusses.

Each of the racks is equipped with hinges, through which they are mated through flanges with the nearest inclined or vertical belt of the barrel of the tower - on the one hand and with the foundation - on the other, to change the distance from the axis of the hinge, paired

the nearest tower belt, to the hinge axis, coupled to the tower foundation with an increase in the total area of the foundation support surface, depending on the height of the tower, its operating conditions and equipment hung on it.

However, a significant drawback of this design is that hinges are installed at the junctions of the section belts with the support section, due to this, the design diagram of the tower changes significantly and the necessary immutability of the structures is not ensured, and therefore its reliability and stability.

The closest analogue of the claimed group of inventions is a trihedral lattice tower, known from RU 106912 U1 (priority from 05/05/2011)

The tower is a trihedral metal structure in the form of a truncated pyramid, the edges of which are formed by belts connected in each face by lattice elements: struts and braces. Belts are made of a trough-shaped profile.

The use of such a tower allows serial production of tower structure elements at the plant, completely eliminating the use of welding at installation, increasing the bearing capacity and stability of tower structures while significantly simplifying its manufacture using a relatively small number of standardized elements, and also provides increased reliability and durability of structures .

However, the use of such a tower is associated with a number of drawbacks, namely, that the design of such a tower is not collapsible, the trough-shaped profile has a large windward area, and there is no indication that the tower of this design can be installed without using an underground foundation.

Based on the analysis of the shortcomings of the known technical solutions, goals were identified that can be solved using the claimed group of inventions.

The aim of the claimed group of inventions is to optimize the time and material costs for the design, manufacture and installation of light collapsible towers up to 50 m high, designed for various equipment and different climatic regions.

For this, prismatic, pyramidal, as well as a support section with inserts that allow you to change the base of the tower.

The technical result of the claimed group of inventions is the ability to change the bearing capacity of a light collapsible tower up to 50 m high depending on its location (climatic region), by replacing one or two lower prismatic tower sections with pyramidal ones and adding inserts between all-welded flanges to the support section trihedral struts in order to increase the base to increase the bearing capacity and stability of the tower on the weights.

Moreover, for the installation of such a design of a collapsible tower up to 50 m high, an underground foundation is not required.

The exclusion of the use of welding during installation of the claimed group of inventions, due to the use of a flange connection of elements, can significantly simplify the installation of structures and reduce the violation of the anti-corrosion coating and makes the structure collapsible.

The invention allows to choose the best option for the design of the tower, in accordance with the loads from the equipment being placed and the climatic region of construction. And the lack of the need for an underground foundation, reduces construction time and facilitates land allocation for the installation of the tower.

The essence of the claimed invention

A tower that does not have a foundation buried in the ground is called a tower on the weights. From the movement and tipping over such a tower is held by loads placed on the supporting frame of the tower. The support frame is connected to the portal (support) section of the tower.

For a tower on weights, not only the mass of weights is important, but also how they are placed relative to the axis of the tower.

It is known that the strength of the tower metal structures, taking into account the antenna-feeder equipment, the height of its placement, the climatic characteristics of the construction area, is affected not only by the mass of weights loading the base plate, but also by the distance by which the weights should be separated from the tower axis. Therefore, it is important to develop and apply the design of the tower, ensuring the strength of the tower in the place of its installation.

To solve this issue, a tower with a variable support section was developed.

The first option is a trihedral lattice collapsible tower on weights up to 50 m high, including several prismatic sections and one supporting section made of welded trihedral struts with a constant geometric pattern, interconnected by flanges.

The second option is a trihedral lattice collapsible tower on weights up to 50 m high, including several prismatic sections, one pyramidal and one supporting section, made of welded trihedral struts with a constant geometric pattern, interconnected by flanges, and to increase the axial size of the supporting sections between the flanges of the connection of the struts of the support section are horizontal inserts.

The third option is a trihedral lattice collapsible tower on weights up to 50 m high, including several prismatic sections, two pyramidal sections and one supporting section made of welded trihedral struts with a constant geometric pattern, interconnected by flanges, and to increase the axial size of the supporting section between the flanges of the connection of the struts of the supporting section are horizontal inserts of a larger size than the insert of a trihedral lattice collapsible tower on the Igruza up to 50 m high in the second version.

Three options for the tower are presented in figures 1, 3, 5.

The Figure 1 presents a trihedral tower, consisting of several prismatic sections and one supporting section without inserts.

The trihedral lattice collapsible tower on weights up to 50 m high includes several prismatic sections and one supporting section made of welded spatial trihedral struts with a constant geometric pattern, interconnected on flanges.

Figure 2 presents a scan of the support section of the trihedral tower, which is presented in Figure 1, which includes only the prismatic sections and the support section without inserts.

Figure 3 shows a trihedral tower, consisting of several prismatic sections, one pyramidal and supporting section with a smaller insert B1.

This triangular lattice collapsible tower up to 50 m high at the weights includes several prismatic sections, one pyramidal and one supporting section made of welded spatial trihedral struts with a constant geometric pattern, interconnected on flanges through horizontal inserts B1 to increase the axial size of the supporting sections.

Figure 4 presents a scan of the supporting section of the trihedral tower, which is shown in Figure 3, with smaller inserts B1.

размера.The Figure 5 presents a trihedral tower, consisting of several prismatic sections, two pyramidal and one support section with B2 inserts

size.

This triangular lattice collapsible tower up to 50 m high at the weights consists of several prismatic sections, two pyramidal, and one support section made of three welded trihedral struts with a constant geometric pattern, interconnected on flanges through horizontal inserts B2 to increase the axial support section size.

Figure 6 presents a scan of the support section of the trihedral tower depicted in Figure 5, with larger inserts B2.

Thus, the proposed line of trihedral towers includes the following types of towers:

- Trihedral lattice collapsible tower up to 50 m high at the weights, including several prismatic sections and a support section without inserts (Figure 1);

- A triangular lattice collapsible tower up to 50 m high at the weights, including several prismatic sections, one pyramidal and supporting section with inserts B1 that increase the axial size of the supporting section (Figure 3);

- A triangular lattice collapsible tower up to 50 m high on weights, including several prismatic sections, two pyramidal sections and a support section with B2 inserts that increase the axial size of the support section (Figure 5).

The supporting section of each tower is made of three welded spatial three-sided struts with a constant geometric pattern. The struts are interconnected on the flanges (without inserts or through inserts). To increase the axial dimensions of the support base of the support section, two insert options are additionally provided: B1 is a smaller insert (Figure 4) and B2 is a larger insert (Figure 6). The inserts, also on the flanges, are mounted between the flanges of the strut connection.

If struts are interconnected without additional inserts, a support section is formed with minimal axial distances. Such a support section is used in a tower consisting of only prismatic sections and one support section (Figure 1).

The support section (Figure 4) with inserts (B1) of a smaller size is used in a tower with one pyramidal section and several prismatic (Figure 3). A tower of this design is designed for a greater load than the tower shown in Figure 1.

The support section (Figure 6) with inserts (B2) of a larger size is used in a tower with two pyramidal sections and several prismatic (Figure 5). With this design, the tower will withstand a large load in comparison with the two previous ones presented in Figures 1 and 3.

Thus, a group of inventions is proposed as an invention, including variants of a trihedral lattice tower up to 50 m high at weights, in the design of which it is possible to significantly change - increase - the bearing capacity of the tower by replacing one or two lower prismatic sections with pyramidal sections and adding the support section of the larger inserts between the flanges of all-welded trihedral struts in order to increase the base of the tower.

Claims (3)

1. Triangular lattice collapsible tower on weights up to 50 m high, including several prismatic sections and one supporting section made of welded trihedral struts with a constant geometric pattern, interconnected on flanges designed to allow the installation of additional horizontal inserts for the purpose increase in axial size of the support section. 2. The trihedral lattice collapsible tower according to claim 1, characterized in that it further comprises one pyramidal section, and horizontal inserts are located between the connecting flanges of the struts of the support section to increase the axial size of the support section. 3. The trihedral lattice collapsible tower according to claim 2, characterized in that it further comprises one pyramidal section, and to increase the axial size of the support section between the connecting flanges of the struts of the support section, horizontal inserts are larger than the inserts of the trihedral lattice collapsible towers according to claim 2 of the formula.

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