RU104583U1 - Rafter Farm - Google Patents

Abstract

 1. A truss truss containing upper, lower chords and a grill, each chord is made of two rolling corners, between which there are chamfers with which the lattice rods are rigidly connected, characterized in that the truss is equipped with rigid inserts placed between the rolling corners of each of the chords and rigidly connected with the indicated corners, while the distance between the hard inserts is selected from the condition: where! L is the distance between the rigid inserts in the truss belts, cm; ! l is the distance between the struts that connect adjacent rafter trusses at the level of the upper and lower zones, cm; ! λy is the ultimate flexibility of the corner of the compressed truss belt; ! λvp - ultimate flexibility of the compressed truss belt in the transverse direction; ! Δ = δ + 2x0 is the distance between the centers of gravity of the rolling corners of the truss belt, cm, where! δ is the distance between the rolling corners of the farm belt, cm; ! x0 is the distance from the center of gravity of the rolling corner to the outer edge of its shelf, cm,! at the same time, gussets in each belt of the farm are placed on both its corners. ! 2. The truss truss according to claim 1, characterized in that the rigid inserts are placed between gussets mounted on the corners of the truss belt and are rigidly connected with said gussets. ! 3. The truss truss according to claim 1, characterized in that the length of each rigid insert along the length of the truss belt is = 8-35 mm. !four. The truss truss according to claim 1, characterized in that the rigid insert is made in the form of a channel. ! 5. The truss truss according to claim 1, characterized in that the rigid insert is made in the form of an I-beam. ! 6. Rafter truss according to claim 1, characterized in that the rigid insert is made of two corners, rigidly interconnected, for example, by

Description

The utility model relates to the field of construction, in particular, to truss trusses, which serve to maintain the roof structure and the perception of the loads acting on it.

A well-known farm type "Zhytomyr" containing the upper and lower zones, interconnected by a diagonal lattice. The upper belt of the farm is made of a rolling I-beam, and the lower belt and a diagonal lattice are made of rolling equal-angle corners. Adjacent rafter trusses are connected by spacers at the level of the upper and lower zones (see V.I. Trofimov, A.M. Kaminsky “Lightweight metal structures of buildings and structures” M., “ASV”, 2002, pp. 103-105).

A segmented truss is also known, comprising an upper and lower belt, interconnected by a triangular diagonal lattice. At the same time, both the lower and upper belts are made of two channels joined to each other (see RF patent for utility model No. 81744 IPC Е04С 3/04).

The described truss structures have increased rigidity due to the fact that the upper belt is made in the first case of I-beams, and in the second of two channels joined to each other. As a result, the designs chosen as analogues can significantly reduce the number of struts with which adjacent trusses are connected. Nevertheless, for the same reasons (the execution of belts from an I-beam or two channels joined with each other), the metal consumption of the belts increases, and therefore the whole farm, which is a significant drawback.

For the prototype, a truss truss containing the upper, lower belts and a lattice was selected. The upper and lower chords are made of two rolling corners, between which there are gussets (shaped sheets), to which lattice rods are attached on both sides (see K.K. Mukhanov “Metal Structures. Design Basics” M., “State Publishing House for Literature on construction, architecture and building materials ”, 1963, p.219-235, fig. VII.30, VII.17a-c). A design similar to the prototype is also presented in the book of N. S. Streletsky et al. “Metal Structures” M., “State Publishing House of Literature on Construction, Architecture and Building Materials”, 1961, p. 407, Fig. X.38.

The metal intensity selected for the prototype truss truss below, described above as analogues. However, the rigidity of this truss truss is also lower, which necessitates an increase in the number of struts that connect adjacent truss trusses at the level of the upper and lower chords. In addition, in some cases (for example, with an increase in the load on the roof), it is additionally required to reduce the distance between neighboring farms, which accordingly entails an increase in the number of farms in the building or structure.

The technical task of the utility model was to create the design of the truss truss, which has both low metal consumption and increased rigidity.

The essence of the utility model lies in the fact that the truss truss containing the upper, lower chords and a grate, with each chuck made of two rolling corners, between which there are chamfers with rigidly connected lattice rods, equipped with rigid inserts located between the rolling corners of each from belts and rigidly connected with the indicated corners, while the distance between the hard inserts is selected from the condition:

where

L is the distance between the rigid inserts in the truss belts, cm;

l is the distance between the spacers (not shown in the drawings) that connect adjacent rafter trusses at the level of the upper and lower zones, cm;

λ _y - ultimate flexibility of the corner of the compressed belt of the farm (selected according to SNiP II-23-81 * "Steel structures");

λ _VP - ultimate flexibility of the compressed truss belt in the transverse direction (selected according to SNiP II-23-81 * "Steel structures");

Δ = δ + 2x ₀ is the distance between the centers of gravity of the rolling corners of the truss belt, cm, where

δ is the distance between the rolling corners of the farm belt, cm;

x ₀ is the distance from the center of gravity of the rolling corner to the outer edge of its shelf (selected according to GOST 8509-93 and / or GOST 8510-86 *), cm,

while the chamfers in each belt of the farm are fixed on both of its rolling corners.

In addition, rigid inserts can also be placed between the gussets, which are fixed on both corners of each farm belt, and are rigidly connected with them.

The length of each rigid insert along the length of the truss belt is = 8-35 mm.

The proposed design of the truss truss has lower metal consumption (compared with the trusses given above as analogues), but greater rigidity (compared with the truss selected as a prototype). This allows for flights longer than 18 m to reduce by 1.4-2.5 times the number of spacers that connect adjacent rafter trusses of the claimed design. At the same time, in cases of using the claimed design of the truss truss in spans of less than 18 m, spacers can be completely abandoned.

The utility model is illustrated by drawings, where Fig. 1 shows a general view of a truss truss; in Fig.2 a view along arrow A of the truss truss in Fig.1, and in Fig.3 a section along BB in Fig.1.

The truss truss contains an upper girdle 1, a lower girdle 2 and a grating 3. Each girdle contains two rolling corners 4 and 5, which are equipped with gussets 6 and 7. The bars of the grating 3 are rigidly connected to the gussets. Between the rolling corners 4, 5 or between the gages 6 and 7 there are rigid inserts 8, which are rigidly connected with the indicated corners or gussets. Rigid inserts 8 can be made of a channel, an I-beam, two corners by welding metal strips to them, a volumetric polyhedron, for example, in the form of a welded square or rectangular box, etc.

The distance between the rigid inserts 8 is selected from the condition:

where

L is the distance between the rigid inserts in the truss belts, cm;

l is the distance between the spacers, (not shown in the drawings) that connect adjacent rafter trusses at the level of the upper and lower zones, cm;

λ _y - ultimate flexibility of the corner of the compressed belt of the farm (selected according to SNiP II-23-81 * "Steel structures");

λ _VP - ultimate flexibility of the compressed truss belt in the transverse direction (selected according to SNiP II-23-81 * "Steel structures");

Δ = δ + 2x ₀ is the distance between the centers of gravity of the rolling corners of the truss belt, cm, where

δ is the distance between the rolling corners of the farm belt, cm;

x ₀ is the distance from the center of gravity of the rolling corner to the outer edge of its shelf (selected according to GOST 8509-93 and / or GOST 8510-86 *), cm,

at the same time, the gussets in each farm belt are fixed at both its corners.

In addition, rigid inserts can also be placed between the packings, which are fixed on both corners of each farm belt, and are rigidly connected with them.

The length (c) of each rigid insert along the length of the truss belt is calculated depending on the load on this truss and ranges from 8 to 35 mm. Performing a rigid insert with a length of less than 8 mm does not make sense, since it will not (not capable) fulfill its purpose, namely, to increase the rigidity of the truss. Performing a hard insert of more than 35 mm is not effective, since a further increase in its length does not increase the rigidity of the truss, but it increases its metal consumption.

Claims (7)

1. A truss truss containing upper, lower chords and a grill, each chord is made of two rolling corners, between which there are chamfers with which the lattice rods are rigidly connected, characterized in that the truss is equipped with rigid inserts placed between the rolling corners of each of the chords and rigidly connected with the indicated corners, while the distance between the hard inserts is selected from the condition:

Where L is the distance between the rigid inserts in the truss belts, cm; l is the distance between the struts that connect adjacent rafter trusses at the level of the upper and lower zones, cm; λ _y - ultimate flexibility of the corner of the compressed belt of the farm; λ _VP - ultimate flexibility of the compressed truss belt in the transverse direction; Δ = δ + 2x ₀ is the distance between the centers of gravity of the rolling corners of the truss belt, cm, where δ is the distance between the rolling corners of the farm belt, cm; x ₀ is the distance from the center of gravity of the rolling corner to the outer edge of its shelf, cm, at the same time, gussets in each belt of the farm are placed on both its corners. 2. The truss truss according to claim 1, characterized in that the rigid inserts are placed between the gussets mounted on the corners of the truss belt and are rigidly connected with the gussets. 3. The truss truss according to claim 1, characterized in that the length of each rigid insert along the length of the truss belt is = 8-35 mm. 4. The truss truss according to claim 1, characterized in that the rigid insert is made in the form of a channel. 5. The truss truss according to claim 1, characterized in that the rigid insert is made in the form of an I-beam. 6. The truss truss according to claim 1, characterized in that the rigid insert is made of two corners rigidly connected to each other, for example, by welding metal strips to them. 7. The truss truss according to claim 1, characterized in that the rigid insert is made in the form of a volumetric polyhedron, for example, in the form of a welded square or rectangular box.