UA23905U - Tower as three-dimensional frame - Google Patents

Abstract

Tower as three-dimensional frame has configuration of truncated pyramid that has straight ledges with flanges connected to each other by means of rigid spacers with corner plates at ends. Sections of tower are assembled with increasing in height number of panels grouped in blocks with same length oftubular ledges and diagonal rods made of round steel. At that one end of diagonal rod is fixed on the upper welded to ledge near flange corner plate of one panel. The other end is arranged with possibility of displacement with respect to axis of angle brace through tension by means of one-side threaded tension element fixed at installed lower corner plate of opposite ledge of the same panel.

Description

Description of the invention

The useful model relates to the construction of steel lattice towers and can be used in the design and construction of support structures for radio and television antennas, antenna-feeder communication equipment, observation posts, wind energy installations, etc.

It is known that there is not a single modern branch of industry that in one way or another did not depend on the existence and successful operation of such devices as tower structures. The costs of materials and means for the manufacture, assembly and installation of high-rise structures, which serve to support wires or equipment, 70 reach enormous sizes, and the radius of their interaction with the surrounding space is many kilometers | Sokolov

A.G. Supports of power lines. - M.: State. edition with letters on construction, architecture and building materials, 1961, 170 p.; Pavlovsky V.F., Kondra M.P. Steel towers (design and installation). - Kyiv:

Builder, 1979, 200 p...

The most common is the design of the tower, the geometric scheme of which fits into the figure formed by the broken line 72 around the vertical axis. A regular polygon lies in any intersection. The tower consists of pyramidal or prismatic sections with connected bases. A tower of this design can have three, four, six, eight or more faces.

When implementing a tower of any design, the task of minimizing manufacturing, assembly and installation costs, on the one hand, and ensuring the reliability of the design, on the other hand, inevitably arises.

A well-known lattice tower, which includes the lower pyramidal and upper prismatic parts, made of sections, and has equal geometric dimensions in plan at the point of their connection (see description to author of St. USSR Mo737610, M. cl.

ЕО4НИ12/08, publ. 30.05.8001, in which the upper belt of the pyramidal part is made removable to pass sections of the prismatic part, while between the lower and upper parts a prismatic insert with horizontal faces parallel to the faces of the tower is installed, and vertically located rods are placed at the points of connection of each pair of faces of the insert , and in the insert there are holes for fastening the mounting element, which perceives the overturning moment acting on the upper part of the extending tower.

The tower design described above provides a minimum of work at height, a large front of work on the ground, requires a minimum amount of equipment, and has the ability to perform installation in conditions of a compressed site. In the final result, the labor intensity and time of installation are reduced, its quality is increased, and the cost of the structure is reduced. Ha")

However, the use of such a structure requires repeated use of the lifting crane, which does not contribute to the reduction of the assembly platform, and the placement of additional elements of the metal structure increases the metal capacity of the tower as a whole. co

A pyramidal lattice tower is also known, which has belt pyramids on its edges and lattice rods on its faces, 39 which in tiers form trapezoidal panels, limited by sections of belts and nodes of lattice rods (see the description of the patent document of the Russian Federation Mo2165505, M. cl. ЕО4НИ12/08 , publ. 20.04.01, in which the height-connected panels are grouped into pairs with the same belt length and into geometrically similar pairs, and a pair of adjacent panels having the same length of belt sections is joined from below by a panel geometrically similar to the lower panel of the specified pairs, " and above - the panel is geometrically similar to the upper panel of the specified pair, and to the pair of neighboring pairs geometrically From similar panels, a panel with the same belt length as in the lower panel of the similar pair adjoins from below, and from above - a panel that has the same length of the belts as in the upper panel of a similar pair. c" The technical result of the above-described design solution is an increase in the unification of the lengths of the belts (twice compared to a similar tower with a geometry physically similar dimensions), as well as increasing the uniformity of nodal connections (2 times compared to a similar tower with a modular breakdown of panels).

However, this tower design assumes the main method of tower installation is the method of building up element by element or section by section with the help of a self-moving crane or in blocks of several sections by a truck crane with a large load capacity, which is currently expensive and inconvenient due to the limited number of such cranes with the accompanying difficulties of the work of installers at height. і-о The closest in terms of purpose, technical essence and the result they achieve when used is the tower av | 20 in the form of a spatial truss, having the shape of a truncated pyramid, containing rectilinear belts of pipes with flanges, which are connected to each other by means of rigid spacers with half-shaped ends at the ends |see. Sokolov A.G. sl Supports of power lines. - M.: Dnrzh. edition with letters on construction, architecture and building materials, 1961, p. 79, fig. 57 and 59). The prestressed braces were made of round steel and had tension couplings (ropes). The pre-stressed braces are attached with one end to the shapes that are welded to the belts of 29 flanges, and with the other end through the talrep at the middle point of the rigid strut, where all four braces from this panel converge. The spatial truss had three rectilinear belts of pipes, the eighteen lower panels were 8 m long, and the upper panels were 4 m long. Each starting mark of the belt ended with a flange. The spacers had half-pieces at the ends, which during installation were clamped between two adjacent flanges, which were connected with bolts. Flexible braces were attached to the shapes welded to the belts at the flanges. In the two lower panels, 60 braces were made solid in order to evenly distribute the forces on the foundations.

The tower had a height of 205 m, and in the case of building supports of a lower height, it was proposed to build them from the appropriate number of higher sections, but at the same time, in one or two lower panels, rigid braces should be installed.

The tower described above had a sufficient number of unified parts, which made it possible to reduce the cost of manufacturing such towers.

However, when assembling on the ground in blocks or sections, and when installing at a height, it is even more difficult to connect four elements at once into one node and under one bolt (two adjacent flanges, and two half-shaped struts between them). At the same time, maintenance and adjustment of braces pre-tensioned with double-threaded guy ropes can be performed only with special suspension equipment. In addition, it is worth considering that the pre-tensioning of the braces implies a slight change in linear dimensions, and therefore the use of double-sided lanyards is impractical, since their manufacture is sometimes impossible due to the rarely used threading tool with a left-hand thread.

The above-mentioned circumstances, as well as the complexity and inconvenience during installation, lead to an increase in the weight of 70 metal structures, to an increase in the cost of installation and construction as a whole.

Therefore, the purpose of the proposed technical solution is to reduce costs for the manufacture and installation of a spatial farm in the form of a truncated pyramid.

The basis of the useful model is the task of improving the tower in the form of a spatial truss, in which, due to the construction of sections of the tower with an increasing number of panels in height, grouped into blocks with the same /5 LENGTH of tubular belts, the construction of braces with round steel bars, fixing one end of each brace on the upper profile welded to the belt near the flange of one panel, the execution of the second end of the brace with the possibility of movement relative to the axis of the brace by tensioning with the help of a one-sided threaded tension element fixed on the lower profile opposite to the belt of the same panel, provides a technical effect that consists in that the construction of each trapezoid or rectangle in the panel, then in the whole bath, and then in the assembled section and the tower as a whole becomes pre-stressed and rigid. Due to the increase in rigidity of the structure as a whole, the possibility of assembly and installation in a horizontal position on the ground with subsequent overturning is ensured in a vertical position of a fully assembled tower, keeping the structure in one point at a tower height of 70 m or more. The lifting point can be made at a length of, for example, 30-35 meters, which is absolutely unacceptable on structures without prestressing (they will simply break under their own weight).

The task is solved by the fact that in a well-known tower in the form of a spatial truss, which has the shape of a truncated o, a three-sided pyramid, containing rectilinear belts with flanges, connected to each other by means of rigid struts with shapes at the ends, according to a useful model, the section of the tower assembled with an increasing number of panels in height, grouped into blocks with the same length of tubular girders, and bar braces made of round steel, while one end of each brace is fixed to the upper welded to the girdle near the flange of the shape of one panel, and the other end is made with the possibility movement relative to the axis of the brace by tensioning with the help of a single-sided threaded tensioning element fixed on the lower-mounted shape opposite the Ф belt of the same panel.

According to a useful model, the braces of any panel, starting from the second, are made crosswise to each other and through the entire panel and are pre-tensioned. with

According to the useful model, the lower section is trihedral with two rows of panels, and the lower row of panels is semi-diagonal.

According to the useful model, the number of panels in the block varies from two to four depending on the height of the tower.

According to a useful model, the second end of each brace is made with a thread, with the help of nuts " fixed on a crosspiece attached to a shape, which is installed below in the opposite belt of the same panel. c c According to a useful model, the second end of each brace, made with a thread, passes through a hole in the traverse. ;" According to a useful model, a crossbar with a hole is attached to the second end of each brace, and a rod rod is fixed at one end to the formwork, which is installed in the opposite belt of the same panel, which has threads and nuts at the other end. According to a useful model, the second end of the bar rod, fixed on the template installed in the opposite belt of the same panel, made with a thread, passes through the hole in the traverse. o According to the useful model, spacers are made from corners.

Ge) As can be seen from the summary of the essence of the decision, which is declared, it differs from the prototype and, therefore, is new.

Known intersection points of braces | see Pavlovsky V.F., Kondra M.P. Steel towers (design and installation). - Kyiv: Budivelnyk, 1979. p. 30-33rd The main nodes, the quality and quantity of which largely depends on the reliability of the structure, its metal capacity, the ease of erection and the cost of the tower, include the nodes of placement and crossing of braces.

The proposed solution is fundamentally different from the known ones in that it allows, as noted above, Assembly and installation to be carried out in a horizontal position on the ground with subsequent overturning of the fully assembled tower into a vertical position, keeping the structure in one point at a tower height of 70 m. The lifting point can be at a length of 30-35 meters, which is absolutely unacceptable on structures without preliminary tension (they will simply break under their own weight).

The proposed solution is industrially suitable and was used in the construction of H-70 base stations of Mobile Communications in the Kirovohrad region, Novgorodkivskyi district, village Tarasivka, Bobrynetsky district, village

Kukolovka et al. Krasnosel'e, Aleksandrivsky District, etc. on the basis of the working project of CJSC "Ukrainian Mobile Communications" according to the standard (35M-900.

The design of the tower in the form of a spatial truss is presented in the drawings.

Fig. 1 Scheme of the tower. 65 Fig. 2 Scheme of a section with two panels.

Fig. 3 A node of flange and two braces.

Fig. 4 Node of strut and two braces.

Fig. 5 The first version of the tension node.

Fig. 6 The second version of the tension node.

The tower in the form of a spatial truss (fig. 1), has the shape of a truncated pyramid, contains rectilinear belts 1 with flanges 2, the belts are connected to each other with the help of rigid spacers Z, made of corners and fixed at the ends on shapes 4, 5 (fig. .3, 4). The sections of the tower are assembled in two-piece panels, grouped into blocks with the same length of tubular belts 1 and made with bar braces 6 running across, while one end of each pair of bar braces is fixed to the upper shapes 4 or 5, which are welded either to the girdle near the 7/0 flange of one panel, or to the girdle at the point dividing it into the panel. The second end is made with the possibility of movement relative to the axis of the brace b by tensioning with the help of a one-sided threaded tensioning element fixed on the shape 7 installed above the flanges of the opposite belt of the same panel, or on the shape 5.

Option 1 (fig. 5). One end of the brace b has a cut 8 for articulation with the cut 7. The second end of the brace 6 is made with a thread, with the help of nuts 9 it is fixed on the traverse 10 with a hole, welded to 7/5 of the cut 11, which is installed in the opposite belt of the same panel on the cut 5 or 7. The second end of the brace 6 passes through the hole in the traverse 10. The first option will be used in the manufacture of a structure made of black metal with subsequent application of anti-corrosion paint to it.

Option 2 (fig.b). One end of the brace 12 has a cut 8 for articulation with a cut 4 or 5. A traverse 13 with a hole is attached to the other end of the brace 12, and on cuts 4 or 5, which are installed in the opposite 2o of the belt of the same panel on the cut 14, a rod is fixed at one end rod 15, which has a thread and nuts at the second end. The second end of the bar rod 15, fixed on the shapes 4 or 5 with the help of the shape 14, installed in the opposite belt of the same panel, is made with a thread and passes through the hole in the traverse 13. The second option is used in the manufacture of a structure made of galvanized black metal.

In the project, the calculation of the H-70.50m tower was performed for all types of load, the self-weight of metal structures on supports and antenna equipment, for wind load taking into account the influence of wind flow pulsations.

The estimated temperature of the coldest five-day period with a security of 0.98 is taken to be -20 C. The antenna, the support is designed in the form of a tower with a height of Н-70.50Ω.

Structurally, the tower is made of two parts: - the lower one from the mark 0.000 to the mark 60.500 - truncated pyramidal, trihedral, lattice with the size of the sides in the plan of the upper base 1350.00mm and the lower 7600.00mm; - the upper one from the mark 60,500 to the mark 70,500 - prismatic, three-sided, lattice with the size of the side o in the plan 1350.00mm. F

In the cross section of the tower there are diaphragms located in accordance with Snip 11-23-817 item 16.177,

The tower is made of separate elements that are connected to each other with the help of bolts. and,

Belts are made of hot-deformed pipes 10.00 m long and connected to each other with the help of flange connections.

Play towers between the marks 0.00 and 5.00 - semi-spanning (fig. 1), braces of 16 tubular cross-section, spacer from a single corner.

Play towers between marks 5.00 and 70.00 - cross, braces are prestressed from round bar « 70 steel, struts from single corners. 8 s In the tower, there are stairs-ladders (not shown in the figure) with a basket fence, after 10.00 m of the platform and for rest during the ascent. A fence is provided on the sites. The platforms and posts of the fence "" are attached to the tower structure with bolts. The horizontal elements of the fence are attached to the fence posts by assembly welding.

The use of pre-stressed round bar braces instead of the traditionally used rigid corner or tubular ones facilitates the construction of the tower up to 1595, and in comparison with quadrilateral towers of a similar height up to 4095. At a tower height of 70 m with corner girders, rigid corner struts and braces of the required bearing capacity it is possible to use only a four-sided design, the weight of which (Te) ranges from 21.5 to 24 tons. A tower of a similar height of a trihedral structure with tubular girders, corner braces and pre-stressed braces can carry the same loads, and in some cases even greater loads, weighing up to 14 tons, which is 6095 times the weight of towers with rigid corner braces. sl At the same time, the tower does not lose the rigidity of the structure, and provides resistance to pulsating wind loads, including oscillations around the axis, the deviations of which cannot exceed more than 0.595 during the operation of radio relay communication systems. with

Claims (9)

The formula of the invention 1. A tower in the form of a space truss, having the shape of a truncated trihedral pyramid, containing rectilinear bo belts with rlanches, connected to each other by means of rigid struts with shapes at the ends, which is distinguished by the fact that the sections of the tower are assembled with increasing height panels, grouped into blocks with the same length of tubular girders and round steel bar bracings, while one end of each bracing is fixed to the top welded to the girdle near the flange of one panel, and the other end is made with the possibility of movement relative to the axis of the bracing by tensioning with a one-sided threaded tensioning element, 65 fixed on the below-installed pattern of the opposite belt of the same panel. 2. A tower in the form of a spatial truss according to claim 1, which is characterized by the fact that the braces of any panel, starting from the second, are made crosswise to each other through the entire panel and have a preliminary tension. C. A tower in the form of a spatial truss according to claim 1, which is characterized by the fact that the lower section is made trihedral with two rows of panels, and the lower row of panels is made semi-diagonal. 4. A tower in the form of a spatial farm according to claim 1, which differs in that the number of panels in the block varies from two to four depending on the height of the tower. 5. Tower in the form of a spatial truss according to claim 1, which is characterized by the fact that the second end of each brace is made with a thread, with the help of nuts, it is fixed on the traverse attached to the shape, which is installed below in the opposite belt of the same panel. 70 6. A tower in the form of a spatial truss according to claim 1, which is characterized by the fact that the second end of each brace, made with a thread, passes through a hole in the traverse. 7. A tower in the form of a spatial truss according to claim 1, which is characterized by the fact that a crossbar with an opening is attached to the second end of each brace, and a bar rod is fixed at one end to the formwork, which is installed in the opposite belt of the same panel, having at the other end threads and nuts. 8. A tower in the form of a spatial truss according to claim 1, which is characterized by the fact that the second end of the bar rod, fixed on the template installed in the opposite belt of the same panel, made with a thread, passes through the hole in the traverse. 9. A tower in the form of a spatial truss according to claim 1, which differs in that the struts are made of corners. with o iv) "c) (o) (ze) p - I.Y and? name) (95) se) («c) sl 60 b5