RU2412301C1 - Collapsible combined trestlework - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: collapsible combined trestlework for installation of cables and/or pipelines with distance between supports of up to 24 metres comprises vertical supports and horizontal runs, cable structures, cross beams with replaceable platforms for sliding supports of pipelines, internal service platform, installed when required. Vertical supports and horizontal runs, representing triangular space trusses with spacer tubular diagonals, are formed from set of sections with various length from 1.5 and to 6.0 m, joined to each other by means of bolt joints. Vertical supports are connected to foundation at one side, and at the other side - to upper mounting frames, horizontal runs are fixed to upper mounting frames, transverse mounting section bars are fixed to lower pipes of horizontal runs with brackets, stands with height of up to 3.0 m are fixed to mounting section bars by T-bolts, cantilevers for cable stairs are fixed to stands by T-bolts, transverse cross beams with detachable platforms for sliding supports of pipelines are fixed to lower pipes of horizontal runs. Due to unavailability of fixed areas of horizontal runs fixation to upper mounting frames of supports, there is no necessity in rigid linkage of foundation coordinates to length of horizontal runs, which provides for higher flexibility in design. Due to fixation of horizontal runs to upper transition frames by yokes and transverse cross beams to horizontal runs, and also due to use of screwless connectors of cable stairs mounted on horizontal runs, and also sectional clamps of cable stairs to cantilevers and oval holes for bolt connection in bases of stands, there are no points of stresses concentration in structure due to temperature deformations.

EFFECT: using sliding T-shaped bolts to install transverse cross beams, stands and cantilevers makes it possible to even location and horizontal level of cable structures during installation and operation, and to repeatedly use T-bolts, if required to disassemble combined trestlework for transfer to a different area of installation.

18 cl, 8 dwg

Description

The invention relates to the construction of flyovers for the joint laying of cables for various purposes with voltages up to 110 kV inclusively with water or steam heating pipelines with or without an outer pipe diameter of up to 219 mm. In the latter case, the overpass will be cable. When bends from the combined flyover, only heating pipes can be laid on horizontal runs, in which case the overpass section will be a pipeline.

An overpass of a process pipeline is known from RU 3021 U1, F16L 3/00, 16.10.1996, containing intermediate supports and anchor supports consisting of struts, upper and lower traverses, cross ties, longitudinal struts that are installed at the level of the lower traverses, while , traverses and longitudinal struts are made of steel frame filled with concrete. The advantage is the low cost of the elements of the flyover. However, it is impossible to use overpass elements many times. In addition, during the construction process, technological operations are needed to adjust the length of the mounted sections by cutting, welding is used to fasten the ties of girders and supports, racks. A paint and varnish coating is used to protect the metal structures of the technological flyover from corrosion. To install one intermediate support, two foundations are necessary, and one foundation - four foundations.

From SU 1217974 A, E01D 17/00, 03/15/1986 a collapsible overpass for laying pipelines is known, comprising vertical supports and horizontal runs. Horizontal runs consist of two planar trusses, consisting of lower belts, upper belts and braces, interconnected by transverse and longitudinal bonds. Horizontal supports are attached to split supports, which, in turn, are attached to the foundation using foundation bolts. As a result, the material consumption of the flyover is reduced, its installation and dismantling are simplified, and its bearing capacity is increased. However, too many elements are used to make horizontal runs, which complicates the design. In addition, this overpass is not intended for cabling. To protect the metal structures of the flyover from corrosion, a paintwork is used. To install one intermediate support, two foundations are necessary, and one foundation - four foundations.

In all known racks, vertical trusses and horizontal runs use rectangular rectangular trusses made of cold or hot-rolled metal profiles (I-beams, channels and corners), followed by painting for anticorrosive protection by paint and varnish coatings that require regular restoration during operation and compliance with a certain painting technology to ensure the durability of coatings, which is difficult to achieve outside the factory paint conditions.

In the claimed invention, unlike all known analogues, triangular cross-section supports and runs are used from pipes, which leads to a significant reduction in material consumption and wind and snow loads due to the round shape of the supporting structural elements of the vertical supports and horizontal runs, as well as a more durable metal factory-applied zinc coating by hot dip galvanizing and increasing the lifetime of the flyover and reducing the cost of restoration anticorrosive paint and varnish protective coatings during operation.

The universality of the declared flyover is also that it can be structurally both impassable and passable, depending on whether there is a need for a service site.

The objective of the invention is to expand the functionality of the flyover, with the ability to use it both for laying pipes and for laying cables. In addition, the task is to significantly simplify the design itself, to use unified elements for it - sections that are the same for supports and for horizontal runs.

The second task solved by the invention is the reusability of the use of a combined flyover.

The third task solved by the invention is the use of a single support for all sections of the flyover and only one foundation for such support.

The fourth task to be solved by the invention is the use of a metal zinc protective coating, which is more reliable and durable than paint and varnish and requires significantly lower costs for the restoration of the flyover during operation.

The fifth task to be solved by the invention is that due to the lack of fixed locations for attaching horizontal girders to the upper mounting frames of supports, there is no need for a rigid reference of the coordinates of the foundations to the length of horizontal girders, which gives great flexibility in design and eliminates the completion of the flyover by cutting and welding run elements at the assembly site.

The sixth problem solved by the invention is that horizontal runs, together with cable structures, supporting pipe traverses and straight pipe sections, are collected on the ground directly near the foundations, followed by installation by a crane on vertical supports, which excludes the transportation of long runs at the facility to the installation site.

The seventh task to be solved by the invention is the use of cable ladders up to 600 mm wide, mounted with a span of up to 9 meters between the support consoles, allowing cables to be laid over the overpass in a simpler and more reliable way. The use of cable ladders, instead of the traditional laying of cables on cable shelves, welded to horizontal runs with a step of 0.8-1.0 m, can significantly increase the cable capacity of the flyover and reduce its dimensions. Laying on cable ladders with jumpers through 250 mm eliminates the possibility of cable sagging, makes it possible to attach it to jumpers on cable ladders in the right place, install clamps on the jumpers of cable ladders for attaching high-voltage cables, and also use removable cable rollers installed on the side for pulling cables bearing profiles of cable ladders and significantly accelerating and facilitating the installation of cables on the overpass.

Depending on the number of cables laid over the overpass, as well as the assessment of possible additional cabling during operation, cable ladders and support consoles of various designs designed for various safe working loads can be selected for installation, which allows optimizing the design for the tasks and thereby designing cable overpass in the most rational way in terms of material consumption and installation costs.

All these tasks during the aerial installation of engineering networks are achieved through the use of collapsible communication and lighting masts made of steel pipes, which are connected to spatial triangular trusses by spacer tube diagonals, bolted to the eyes of the section bearing pipes, as a supporting structure. It is proposed to use such typical sections of vertical communication and lighting masts for a combined flyover with horizontal runs up to 24 meters and vertical supports up to 10 meters high.

Thus, a collapsible combined overpass for laying cables and / or pipelines contains vertical supports and horizontal runs.

The vertical supports and horizontal runs are formed from a set of sections (preferably identical, that is, having the same geometric dimensions, but in some situations it is possible for the sections to have different lengths), interconnected, which are triangular spatial trusses with a side, preferably about 1 m , with spacing diagonals. Vertical supports are connected on one side to the foundation, and on the other hand to the upper mounting frames. Horizontal runs are attached to the upper mounting frames. Transverse mounting profiles are attached to the lower pipes of horizontal runs, preferably with brackets (or clamps or other suitable detachable fasteners). Racks are attached to the transverse mounting profiles. Consoles for cable ladders are attached to the racks. Transverse travers with removable platforms for sliding supports of pipelines are attached to the lower pipes of horizontal runs.

Each section, which is an equilateral triangular spatial truss, consists of three supporting pipes, which are cylindrical tubular elements having a circular cross section, each supporting pipe is connected to each of the other two supporting pipes using spacing diagonals, which are preferably cylindrical tubular elements having a circular cross-section, with flanges with holes for fasteners in such a way that sec The sections can be interconnected, preferably with nine bolt pairs (one bolt pair is a bolt and a nut), however, the sections can also be interconnected using threaded connections or other detachable threaded or non-threaded connections suitable for the case.

As indicated, it is preferred that the spacing diagonals are tubular elements having a circular cross section. However, the spacer diagonals may be incomplete rods, or beams having a quadrangular cross section, or have some other kind (shape) suitable to serve as spacer elements for the supporting pipes.

Sections can have a length of up to 10 m, preferably from 1.5 to 6.0 m, and are interconnected into vertical supports and horizontal runs in an arbitrary combination of bolted pairs. Racks for mounting cable ladders have a height of up to 10 m, preferably up to 3 m, and are attached to the mounting profiles with T-bolts through the brackets, consoles for cable ladders are attached to the racks with T-bolts.

A removable ladder is attached to the spacing diagonals of the sections of the vertical support for climbing horizontal runs. The supporting pipes and spacing diagonals of each section are made of high-quality steel, intended for applying a zinc protective coating by hot dipping.

The collapsible combined overpass additionally contains transition elements through which horizontal runs can be interconnected to rotate the overpass by a fixed angle of 90 ° or 120 ° or any other angle to the longitudinal axis of the flyover, as well as to raise or lower it in height and form T - and X-shaped overpass bends at right angles.

Racks for mounting consoles for cable ladders are connected to horizontal girders by means of V-braces attached to the upper horizontal run pipe with brackets.

All elements of the sections and all elements of the upper mounting frames are hot dip plated.

To strengthen the design of the end horizontal section, end plates of a triangular shape are attached to it.

To connect the vertical supports to the foundation, installation and drainage disks are used, vertical supports are installed on the installation and drainage disks, while the installation and drainage disks are made with drainage grooves to remove rain moisture and condensate from the internal cavities of the bearing pipes of the vertical support sections.

To strengthen the design of the horizontal run section in places of its support on the upper installation frames, collapsible stiffening belts are used, which are installed to the right and left of the support point of the horizontal run on the upper installation frame.

The horizontal run is installed on the upper mounting frames through the transverse mounting profile - the lower channel, transversely fixed to the run pipes with stainless steel clamps, which makes it possible to horizontally move the section during installation to compensate for inaccuracies in the installation of the foundation on straight sections of the flyover and to provide the necessary rotation angle when turning the flyover axis at an angle other than 90 °.

The upper mounting frame can be adjusted vertically on the support through the use of threaded rods and lock nuts.

Cross beams for mounting pipe supports are installed on horizontal runs using clamps, preferably stainless steel (the mentioned clamps can also be made of other material suitable for this case, for example, plastic or copper), while the platforms for the sliding pipe supports are removable and platforms for pipes of different diameters can be installed on one traverse, which minimizes the range of traverses used.

An overpass can be either a walkway, when installing a ladder on intermediate traverses between racks and mounting an internal service platform installed between racks, or impassable when the ladder and internal service platform are not mounted.

Due to the lack of fixed locations for attaching horizontal girders to the upper mounting frames, there is no need for a rigid reference of the coordinates of the foundations to the length of the horizontal girders, which gives greater flexibility in design and eliminates the completion of the flyover by cutting and welding of girder elements at the assembly site.

Mast sections are used as vertical supports and horizontal girder runs, which can consist of one or several sections of various lengths, interconnected by bolted pairs through end flanges at the ends of the supporting pipes, which together with the spacing diagonals make up the mast sections.

Vertical supports and horizontal runs are prefabricated of arbitrary length, which is achieved by arbitrary combination of sections and allows you to provide the following size range for vertical supports and horizontal runs. Preferably, this size range is a multiple of 0.75 m:

- for vertical supports: 1,50-2,26-3,00-3,75-4,50-5,25-6,00-6,75-7,50-8,25-9,00-9 75 m

- for horizontal runs: 3.00-3.75-4.50-5.25-6.00-6.75-7.50-8.25-9.00-9.75-10.50-11 25-12.00-12.75-13.50-14.25-15.00-15.75-16.50-17.25-18.00-18.75-19.50-20.25 -21.00-21.75-22.25-23.00-23.75-24.50,

however, other variants of size ranges are possible, for example, multiples of 0.5 m or 1 m.

During the construction of such a flyover, technological operations to adjust the length of the mounted sections by cutting and fastening the spacer connections of girders and supports, as well as racks for mounting cable shelves by welding are completely excluded, which makes it possible to quickly disassemble, compactly transport and reuse the flyover if it is necessary to organize power supply to another object in a temporary pattern.

All typical sections and components of the cable ladder system, as well as traverses for mounting sliding and fixed pipe supports, have a hot dip zinc coating, which eliminates the need for priming and painting with anti-corrosion paints after assembling the flyover and regular restoration of the protective coatings for at least 15- 20 years in the most corrosive environments.

Due to the fastening of prefabricated horizontal girders with stainless steel brackets to transition frames mounted on vertical supports, it is possible to longitudinally move the horizontal girder sections during installation, which makes it possible not to design and produce special expansion joints for thermal expansion of the flyover structure. This method of fastening also allows for the rotation of the flyover in the horizontal plane to an arbitrary angle, which makes it possible to more flexibly lay the flyover along the shortest path.

There is the possibility of mounting on horizontal runs with T-bolts, clamps and double-sided C-shaped mounting profiles of the supporting structure (racks, consoles, cable ladders, fasteners) for laying cables of different voltage at several levels in height along cable ladders up to 600 wide mm, ensuring the laying of cables on opposite sides of the longitudinal axis of the flyover with a distance of up to 1 meter horizontally between the nearest cables. On the pipes of the lower part of the girder run, stainless steel clamps are mounted with crossbars with removable platforms for installing sliding supports for heat supply pipelines.

By installing prefabricated frames from the mounting profiles between the racks by fastening them to the supporting pipes of horizontal run, internal ladders can be mounted between the racks for cable maintenance.

It becomes possible to use a single foundation for a vertical support, while for towers of a similar purpose, the construction of 2-4 foundations is required depending on the type of support (intermediate or anchor), which leads to significant savings in concrete and a decrease in excavation work for excavation under foundations .

Figure 1 shows the support collapsible combined overpass with horizontal run and elements for fastening pipes and cables mounted on it, figure 2 - template for installing foundation bolts, figure 3 - assembly on the ground sections of horizontal runs, figure 4 and 4a is a view of a horizontal (vertical) section, in Fig. 5 is a mounting of a staircase to a vertical support, in Fig. 6 is a fastening of a vertical support 21 to a foundation, Fig. 7 is a general view of a collapsible combined flyover (photo), Fig. 8 - collapsible combined overpass with platform serviced i.

The collapsible combined overpass consists of vertical supports and horizontal runs. In this case, the vertical supports 21 and horizontal runs consist of the same mast sections 12 (12a), which are made with the possibility of connecting with each other. The vertical supports 21 are fastened with foundation bolts 1 to the foundation 32. On the vertical supports 21, an upper mounting frame 3 is installed. On the upper mounting frame 3, horizontal runs are installed using the transverse mounting profile 16. The transverse mounting profiles 16 are attached to the lower supporting pipes of 33 horizontal runs by brackets 16. To the transverse mounting profiles, 16 T-bolts fasten racks 10 up to 3.0 m high. Consoles 13 for cable ladders are attached to the racks 10 T-bolts. To the lower supporting pipes 33 of horizontal runs are attached transverse traverses 14 with platforms for supports of pipelines 15.

To increase the corrosion resistance of elements of a collapsible combined flyover, the elements of the mast sections 12 (12a) and the elements (traverses) of the upper mounting frame 3 are coated with a hot dip zinc coating.

Assembling a collapsible combined flyover is as follows.

First, the coordinates of the centers of each support are set. In accordance with these coordinates, holes are made on the surface of the earth 31 and the foundations 32 are installed. The foundation bolts 1 are preliminarily poured into the foundation foundation 32, and the foundation bolts 1 are installed in accordance with the installation pattern shown in FIG. 2. The template has the form of an equilateral triangle, at each apex of which three holes are made for foundation bolts, which also form an equilateral triangle. In this case, the foundation bolts 1 protrude above the upper surface of the foundation to a height of 150-200 mm.

Then collect sections of horizontal runs on the ground (figure 3). As horizontal runs (and also as vertical supports) mast sections 12 are installed, which are installed in the horizontal direction. Each mast section 12, installed in the horizontal direction (hereinafter referred to as the horizontal section 12, Figs. 4, 4a), consists of three load-bearing pipes (supporting elements) 33, which are cylindrical tubular elements having a circular cross section. Each carrier pipe 33 is connected to each of two other adjacent bearing pipes by means of spacing diagonals (braces) 34 to impart structural rigidity. Moreover, the connection of the spacer diagonals 34 with the bearing pipes 33 is made in such a way that in each case two spacer diagonals 34 and one of the bearing pipes 33 form a triangle between themselves. Bearing pipes 33 and spacer diagonals 34 are made of steel. To assemble the horizontal section 12, the spacing diagonals 34 are attached to the eyes 37 on the supporting pipes 33 with bolts 38. Thus, each horizontal section 12 is a triangular spatial truss. At both ends of each of the supporting pipes 33, flanges 35 are made with three holes 36 for fasteners. Using these flanges and fasteners, the horizontal sections 12 are connected to each other in a horizontal run. One section is connected to another section by nine bolted pairs. If necessary, a ladder is attached to the vertical sections 12 for the convenience of lifting the installers to horizontal runs. Preferably, the length of one carrier pipe 33 (and, therefore, one horizontal section) is 6 m. The recommended length of the horizontal run collected on the ground for lifting with one crane is 18 m. Assembly on the ground and subsequent installation on horizontal supports of horizontal runs of length up to 30 m. Horizontal runs during assembly on the ground are laid on parallel wooden supports (goats) or on wooden pallets.

Then carry out the installation of vertical supports on the ground. As the vertical support 21, the mast section is used, the design is exactly the same as the horizontal section. Each mast section, installed in a vertical position (hereinafter, the vertical section 12a, Figs. 1, 4, 4a), also consists of three supporting pipes (supporting elements) 33, which are cylindrical tubular elements having a circular cross section. Each carrier pipe 33 is connected to each of two other adjacent bearing pipes by means of spacing diagonals (braces) 34 to impart structural rigidity. Moreover, the connection of the spacer diagonals 34 with the bearing pipes 33 is made in such a way that in each case two spacer diagonals 34 and one of the bearing pipes 33 form a triangle between themselves. Bearing pipes 33 and spacer diagonals 34 are made of steel. To assemble the vertical section 12a, the spacing diagonals 34 are attached to the eyes 37 on the support tubes 33 with bolts 38. Thus, each vertical section 12a is a triangular spatial truss. At both ends of each of the supporting pipes 33, flanges 35 are made with three holes 36 for fasteners. One section is connected to another section by nine bolted pairs. Using these flanges, the vertical section 12a can be fastened from below to the foundation 32 by means of foundation bolts 1 or to another vertical section 12a by means of fasteners, and can be fastened from above by fasteners to another vertical section 12a or to the upper mounting frame 3. To the spacing diagonals 34 vertical sections using U-shaped brackets 4, mounting brackets 5, gaskets 6, as well as nuts 7 with washers 8, a ladder 9 is attached (Fig. 5). On the supporting pipes 33 and the spacing diagonals 34 before assembling the horizontal (and vertical) sections in the factory, a protective zinc coating is applied by hot dip.

After assembling the vertical sections 12a and attaching the stairs 9 thereto, vertical supports 21 are formed, which may consist of one or more vertical sections 12a. The lower end of the vertical support 21 using the foundation bolts 1, installation and drainage disk 22 and a special washer 11 (BRFB washers 21 × 34 HDG) and nuts 18 are attached to the foundation 32 (Fig.6). The upper mounting frame 3 is mounted on the upper flanges 35 of the vertical support 21. After installing and aligning the vertical supports 21, the foundation bolts under the installation and drainage discs 22 are filled with a special shrink-resistant cement mortar to ensure the rated bearing capacity of the vertical support. Installation and drainage disks 22 are made with drainage grooves to remove rain moisture and condensate from the internal cavities of the section bearing pipes. On the elements (traverses) of the upper installation frame 3, before its installation, a protective zinc coating is also applied by hot dipping in the factory.

Horizontal runs, consisting of horizontal sections 12, are lifted using a crane, mounted on the upper installation frame 3 and fixed on it so that two carrier pipes 33 lie directly on the upper installation frame 3 (hereinafter, the lower carrier pipes 33 of the horizontal section 12 ), and the third carrier pipe is located above the installation frame and the other two carrier pipes 33 (hereinafter, the upper carrier pipe 33 of the horizontal section 12). Horizontal runs are connected to each other in the same way as sections 12 were connected to each other. If there is a need to turn the flyover horizontally and / or vertically, horizontal runs can be connected to each other not directly, but via transition elements. As a result, the overpass can go not strictly in a straight line, but have turns to the right (left), and rise (fall) in height if necessary (for example, if the overpass crosses the highway, or you need to go around a building or a hill). Thus, by means of transition elements, horizontal runs 12 can be interconnected to rotate the flyover by a fixed angle of 90 ° or 120 ° or another angle to the longitudinal axis of the flyover, as well as to raise or lower it in height and form T- and X- right-angled overpass bends.

On the upper mounting frame 3, the transverse mounting profiles 16 are fastened to the lower pipes 33 of horizontal runs 12 with brackets 16. The racks 10 are attached to the transverse mounting profiles 16 with T-bolts. For the stiffness of the rack 10, they are also attached to the upper supporting pipe 33 by horizontal V-braces 11 section 12 (figure 1). In turn, the consoles 13 are attached to the racks 10 with the help of fasteners from the outside. It is preferable that 3-5 racks or more of the consoles 13 are attached to each rack 10, thereby forming several parallel tiers for attaching cable ladders with cables to them for various purposes.

On both sides, to the lower pipes 33 of the horizontal runs 12, using the transverse mounting profile 16, the transverse cross beams 14 are mounted with platforms for supporting the pipe 15. These platforms are plates on which the pipe 15 is installed. Upper mounting frame 3, transverse mounting profile 16 and V-brace 11 are made of stainless steel designed for hot dip galvanizing.

If necessary, between the racks 10, you can install the service platform (Fig.8). This platform, as well as the gangway, are installed between the racks for the convenience of installers laying and maintaining cables and sleeves, assembling or dismantling cable structures (cable ladders), installing additional consoles or dismantling consoles that have become redundant.

The result is an easily and quickly assembled collapsible structure, in which there are no integral joints, there is no need to fit elements to each other by cutting, there are no welded joints. Thus, the elements of a collapsible combined flyover, if necessary, can also be easily disassembled, transported to another place and assembled in a new place.

In other words, a collapsible combined flyover consists of standardized, easily replaceable elements that can be used repeatedly. This leads to a significant reduction in the cost of installation / dismantling and repair of the flyover, as well as the production of its elements. As a result, not only the construction of the flyover is accelerated and cheapened, but its reliability, durability and maintainability also increase.

Although the present disclosure has been described with reference to one or more embodiments, it will be understood by those skilled in the art that other embodiments of the claimed invention may occur, within the scope of the appended claims.

Claims (18)

1. A collapsible overpass for laying cables and / or pipelines, containing vertical supports and horizontal runs, while the vertical supports and horizontal runs are formed from a set of sections interconnected, which are triangular spatial trusses with spacing diagonals, vertical supports are connected on one side with the foundation, and on the other hand with the upper installation frames, horizontal runs are attached to the upper installation frames, attached to the lower pipes of horizontal runs us transverse mounting profiles to transverse profiles of the mounting rack are attached to struts attached console for cable ladders, to the lower horizontal runs of the tubes are fixed transverse crosspiece with movable platforms for pipe supports. 2. A collapsible overpass according to claim 1, characterized in that each section, which is an equilateral triangular spatial truss, consists of three supporting pipes, which are cylindrical tubular elements having a circular cross section, each supporting pipe is connected to each of the other two supporting pipes using spacing diagonals, also representing cylindrical tubular elements having a circular cross-section, with flanges with holes for crepe made on the ends of each of the supporting pipes hedgehogs in such a way that the sections can be interconnected by nine bolted pairs. 3. A collapsible flyover according to claim 1, characterized in that the sections have a length of up to 10.0 m, preferably from 1.5 to 6.0 m, vertical supports and horizontal runs can be assembled into sections of different lengths from the said sections. 4. Collapsible overpass according to claim 1, characterized in that the sections are interconnected by bolted connections. 5. A collapsible flyover according to claim 1, characterized in that the racks for mounting the consoles are up to 3 m high and are attached to the mounting profiles with T-bolts, the consoles for cable ladders are attached to the racks with T-bolts. 6. A collapsible flyover according to claim 2, characterized in that a removable ladder is attached to the spacing diagonals of the sections of the vertical support for climbing horizontal runs. 7. The collapsible combined overpass according to claim 2, characterized in that the supporting pipes and spacer diagonals of each section are made of stainless steel, intended for applying a zinc protective coating by hot dipping. 8. A collapsible flyover according to one of claims 1 to 7, characterized in that it further comprises transition elements by which horizontal runs can be interconnected to rotate the flyover at any fixed angle to the longitudinal axis of the flyover, as well as to lift it or lowering in height or the formation of T- and X-shaped bends of the flyover at a right angle. 9. A collapsible flyover according to claim 8, characterized in that through the transition elements horizontal runs can be interconnected to rotate the flyover by a fixed angle of 90 or 120 °. 10. A collapsible overpass according to one of claims 1 to 7, characterized in that the racks for mounting the consoles for cable ladders are connected to the horizontal runways by means of V-shaped braces attached to the upper horizontal run pipe by brackets. 11. A collapsible overpass according to one of claims 1 to 7, characterized in that all elements of the sections and all elements of the upper installation frames are coated with hot dip zinc coating. 12. A collapsible flyover according to one of claims 1 to 7, characterized in that in order to strengthen the design of the end horizontal section, end plates of a triangular shape are attached to it. 13. A collapsible flyover according to one of claims 1 to 7, characterized in that installation and drainage disks are used to connect the vertical supports to the foundation, vertical supports are installed on the installation and drainage disks, while the installation and drainage disks are made with drainage grooves for removal rain moisture and condensate from the internal cavities of the bearing pipes of the vertical support sections. 14. A collapsible overpass according to one of claims 1 to 7, characterized in that collapsible stiffening belts are installed to the right and to the left of the support point of the horizontal run on the upper mounting frame to strengthen the design of the horizontal run section at the places of its support on the upper mounting frames. 15. A collapsible overpass according to one of claims 1 to 7, characterized in that the horizontal run is installed on the upper mounting frames through the transverse mounting profile — the lower channel, transversely fixed to the run pipes with stainless steel clamps, enabling horizontal movement of the horizontal run section when installation to compensate for inaccuracies in the installation of the foundation on straight sections of the flyover and to provide the necessary angle of rotation when the axis of the flyover is turned by an angle other than 90 °. 16. A collapsible flyover according to one of claims 1 to 7, characterized in that the upper mounting frame can be adjusted vertically on the support by using threaded rods and lock nuts. 17. A collapsible overpass according to one of claims 1 to 7, characterized in that the transverse traverses for mounting the pipe supports are installed on horizontal runs with clamps, while the platforms for the pipe supports are removable, while platforms for pipelines can be installed on one traverse different diameters. 18. A collapsible overpass according to one of claims 1 to 7, characterized in that intermediate traverses are installed between the racks, on which the ladder of the internal service platform is mounted.

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