RU153753U1 - LATTLE SPATIAL NODE OF COVERING (OVERLAP) FROM CROSS FARS OF TYPE "NOVOKYSLOVODSK" - Google Patents

Abstract

The lattice spatial node of the cover (overlap) from cross trusses, including tubular straight-line elements of belts and tubular zigzag elements of diagonal gratings for the entire span with flattened flat ends and sections, characterized in that the joints of the belts and braces, as well as their mutual intersections, are made the same for using a centrally located bolt mount and a single clamping washer, and for covering the gable shape in its ridge zone, flattened flat sections of the element hnego belt one of the intersecting lines are double symmetrical bends and flattened flat portions lower chord member in the same direction - asymmetrical single bends.

Description

The proposed technical solution relates to the field of construction and can be used in lattice spatial structures for the construction of ceilings, coatings, facade systems, frames, skeletons of various buildings and structures.

A solution to the spatial framework of tubular rods with flattened ends in the form of flat tips is known. The assembly of such a frame is carried out by sequential overlapping of the tips of the rods to each other and the corresponding connection of their bolts. The lapping sequence consists in the fact that each tip is wound with its one edge under the previous tip, and the other edge is supported by the subsequent tip [Khisamov R.I. Nodal connection of the rods of the frame. - Copyright certificate No. 594269, 02.25.1978, bull. No. 7]. The described solution differs due to the large number of bolts: at least four bolts per rod. It is possible to use only rod elements that are interrupted at the connection points, and it is also necessary to observe increased accuracy of manufacture and installation.

Another well-known solution is a lattice spatial structure of tubular rods formed by parallel grids with intersecting continuous belts connected to each other in nodes by braces. At the points of intersection, the belts are flattened with the allocation of flat sections that are joined to each other and with bent gussets with the help of centrally located bolts and pressure washers. The ends of the braces are also flattened in the form of flat tips and by means of bolts connected to the fittings [Nechaev I.A.,

Shumitsky O.I. Lattice spatial design. - Copyright certificate No. 473785, 06/14/1976, bull. No. 22]. The use of bent gussets in the connecting nodes leads to an increased consumption of structural material, and the complex shape and double bends increase their labor costs. As in the previous case, only the bar elements that are interrupted in nodes can be used for braces. In this case, for bolted connections of braces with fittings, it is necessary to observe increased accuracy of manufacture and installation.

The closest technical solution (adopted as a prototype) to the proposed one is a spatial truss (structure) of tubular rods formed by belt grids parallel to each other and interconnected in nodes by braces. At the intersection, the core elements of the belts and braces of one direction are interrupted, and the other remain continuous. The rod elements are made with flattened ends in the form of flat tips. In addition, in places dividing in half by their length, they are flattened with the allocation of flat sections. With the help of single bends of flat tips and double bends of the middle sections, the rod elements of the braces are given a V-shape. In connecting nodes that coincide with the intersection, interrupted rod elements of one direction overlap each other and are joined with continuous rod elements of the other direction with centrally located bolts and double pairs of pressure washers [Space truss. - EP 1496166 A1, 12.01.2005, bulletin 2005/02].

The disadvantage of the prototype is that double pairs of clamping washers increase the labor costs of production and the consumption of structural material, and their total thickness is the reason for noticeable misalignment in the connecting nodes. Nodal offsets can result in eccentricities exceeding one fourth of the height of the waist element. In such cases, additional

voltage from moments, which is accompanied by an increase in the material consumption of load-bearing structures.

In addition, in all the above solutions, tubular rods with flattened flat ends and sections at the same intersection form the same flat belt nets, which narrows the layout capabilities of the supporting structures and reduces their versatility.

The technical result of the proposed solution is to reduce the labor costs of manufacturing and consumption of structural material, as well as expanding the layout capabilities of load-bearing structures and increasing their versatility.

The specified technical result is achieved by the fact that in the lattice spatial node of the cover (overlap) from cross trusses, including tubular rectilinear elements of belts and tubular zigzag elements of diagonal lattices for the entire span with flattened flat ends and sections, connecting belts and braces, as well as their mutual intersections are made equally using a centrally located bolt mount and a single pressure washer. To cover the gable shape in its ridge zone, the flattened flat sections of the upper belt element of one of the intersecting directions have double symmetrical bends, and the flattened flat sections of the lower belt element of the same direction have single asymmetric bends.

The proposed technical solution is quite universal. It allows the use of elements of full factory readiness from square (rhombic) or round (oval) pipes with bolted joints at the installation. Moreover, the nodes of the joints of the belts and braces, as well as their mutual intersections differ only in the number of connected elements. In both cases, single clamping washers exert strength resistance to bending from the side of the extended braces. Nodal centerings due to the total thickness of single clamping

washers and flattened elements of the tubular rods, lead to eccentricities, clearly not exceeding one fourth of the height of the waist element.

The universality of the proposed technical solution ensures its use in non-stop coatings. To do this, it is quite enough to use tubular rods of square or rectangular cross section without flattening as the upper zones of the cross structures of one of the directions. At the same time, modification of run-free coatings is possible when run-belt elements alternate with additional runs that divide the cells of the cross-system in half at the level of the upper belts. As an example of such modifications, we can give a gable coating, where flattened flat sections of the upper zones of one of the directions have double symmetrical bends to form a ridge. Moreover, in the corresponding flattened flat sections of the lower zones it is quite enough to have single bends. Here the clamping washers from the side of the extended braces must be supplemented with the same washers from the side of the bent panels of the lower (stretched) belts.

With no less efficiency, the proposed technical solution can be implemented in other spatial modifications (diagonal-cross, cylindrical, spherical, structural).

The proposed technical solution is illustrated by graphic materials, where in FIG. 1 shows a diagram of an orthogonal system of cross farms in assembled form; in FIG. 2 is an exploded view of an orthogonal system of cross farms; in FIG. 3 shows the connection node of the upper belt and the braces of the farm from square (rhombic) pipes; in FIG. 4 - connection node of the upper zones and braces of trusses from square (rhombic) pipes, as well as their mutual intersection; in FIG. 5 - connection node of the upper belt and the braces of the farm from round (oval) pipes; in FIG. 6 - connection node of the upper zones and braces of trusses from

round (oval) pipes, as well as their mutual intersection; in FIG. 7 shows the junction of the upper belts and braces of the trusses, as well as their mutual intersection for the case of limitless coverage; in FIG. 8 is a diagram of an orthogonal system of cross trusses for the case of a gable coating; in FIG. 9 shows the connection unit of the girder, upper belt and braces of the truss with symmetrical double bends of braces and the upper belt (ridge node); in FIG. 10 - connection node of the lower belt and the braces of the farm with asymmetric double bends of braces and a single bend of the lower belt; in FIG. 11 shows a diagram of a diagonal system of cross farms; in FIG. 12 is a diagram of bar cross structures for the case of a cylindrical coating; in FIG. 13 is a diagram of a cross-bar structure for the case of a spherical shape of the coating; in FIG. 14 is a diagram of the structural structure of the coating (overlap); in FIG. 15 is a snapshot of a fragment of a structural structure made of plastic tubular elements; in FIG. 16 is a snapshot of the structural structures of a coating of unified core and nodal elements of the MARCHI, Kislovodsk system.

The proposed lattice spatial node cover (overlap) of cross trusses made using square (rhombic) or round (oval) pipes, includes rectilinear upper (compressed) belts 1 and lower (stretched) belts 2, as well as zigzag diagonal lattices 3 between them . Belts 1, 2 and gratings 3 with the length of the entire structure or its shipping mark are made with flattened flat ends and sections at the sites of nodal joints and mutual intersections. The diagonal lattices 3 have a zigzag shape due to symmetrical double bends of flattened flat sections and single bends of flattened flat ends. Installation of structures begins with the layout of the lower belts 2 of one of the intersecting directions, the same belts 2 are laid out on them

another direction. Lattices 3 are installed on the formed net of lower belts in the same order. Assemble the threaded fasteners of the lower nodal joints and mutual intersections, consisting of centrally located bolts 4 with complete sets of washers and nuts, as well as clamping washers 5 from the side of the braces of the lattices. In accordance with the accepted installation sequence, the upper belts 1 are installed on the upper nodes of the joints and intersections of the grids 3. The threaded fasteners of the upper nodes and mutual intersections are assembled, which are no different from the lower ones. After reconciling the mounted structures, tighten the bolt fasteners counter-clockwise or clockwise, starting from the center and sequentially ending with peripheral ones.

In the construction of non-stop coatings, the upper belts 6 of one of the intersecting directions are performed without flattening square or rectangular pipes. The sequence of installation of such structures should ensure the location of the belts 6 on top of the belts 1. At the same time, the nodal joints and mutual intersections, as well as the chain of technological operations for their implementation, remain the same.

The structures of gable coatings in one of the intersecting directions have ridge nodes and contain upper belts 7, lower belts 8, diagonal grilles 9 between them. The skate assembly is performed using symmetrical double bends of a flattened flat section in the middle of the upper belt 7. In this case, the lower belt 8 can have single bends in two middle flattened flat sections, and the diagonal lattice 9 can have asymmetric double bends in two lower middle flattened flat sections. In the ridge nodes, it is possible to support the runs 10 made of square or rectangular pipes. These runs can alternate with run-belt elements 6, dividing the cells of the cross-system at the level of the upper belts in half. There are also nodal connections and mutual intersections, as well as the chain of technological operations for their implementation remain the same.

A cylindrical coating can be arranged on the model of the gable version if the structures of one of the intersecting directions are given an arched shape. When using arched structures in both intersecting directions, the shape of the coating becomes spherical. Belts and diagonal lattices of cross structures of coatings (floors) can be deployed diagonally. With the arrangement of the diagonal gratings diagonally relative to the waist grids, a structural (crystalline) structure is formed.

As you can see, the proposed technical solution allows you to compose spatial modifications of coatings and ceilings from cross-bar structures assembled from long tubular belts and solid, diagonal gratings of the same length with non-shaped joints on bolts without factory and assembly welding. It is advisable to unify them throughout the span, based on the fact that at present, the practice of designing low-span lightweight metal structures of complete delivery confirms the demand for them in buildings and structures for various purposes [1. Kopytov M.M., Matveev A.V. Lightweight metal structures from five-sided pipes. - Tomsk: STT, 2007 .-- 124 p .; 2. Marutyan A.S. Design of lightweight metal structures from cross systems, including modules of the Pyatigorsk type. - Pyatigorsk: SKFU, 2013. - 436 p.]. So, modules (blocks) of coatings (floors) from cross farms of the Pyatigorsk type, having dimensions in the range of 6 × 6 ... 12 × 12 m, are made entirely welded. However, there are quite often cases where collapsible structures with bolted joints are more preferable. The very common structural modules (sections) of coatings of the MARCHI, Kislovodsk system are assembled on bolts, the number of which in one node can reach 8 ... 10. These bolts in the factory are secured using butt welded parts in the unified rod elements of belts and braces [TU 5285-001-47543297-09. Rods and nodal elements of the system

MARCHES. - M .: LLC SPC "Victoria", 2009. 60 p.]. In the proposed designs, one centrally located nodal bolt connects up to 8 rod elements. And such designs can find that area of rational application where Kislovodsk modules are less effective due to their large dimensions.

Thus, the proposed technical solution is implemented in designs that are likely to find their niche in the series between the Kislovodsk and Pyatigorsk modules. Therefore, it seems advisable and useful to start the project of their experimental studies under the working name of a lattice spatial node of a coating (overlap) from cross farms of the Novokislovodsk type. This can be done on the basis of the Pyatigorsk branch of the North Caucasus Federal University and the Kislovodsk plant of metal structures.

Claims (1)

The lattice spatial node of the cover (overlap) from cross trusses, including tubular rectilinear elements of belts and tubular zigzag elements of diagonal gratings for the entire span with flattened flat ends and sections, characterized in that the joints of the belts and braces, as well as their mutual intersections, are made the same for using a centrally located bolt fastening and a single clamping washer, and for covering the gable shape in its ridge zone, flattened flat sections of the element hnego belt one of the intersecting lines are double symmetrical bends and flattened flat portions lower chord member in the same direction - asymmetrical single bends.

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