SU1278420A1 - Multispan unsplit truss - Google Patents

Abstract

The invention can be used in the construction on subsiding soils. The purpose of the invention is to increase the reliability of operation and control. The multi-span farm does not include the component elements of the lattice 2 of the rolled sections united by connecting fixing parts 6 allowing for the possibility of limited deformations of the elements. Component elements 2 are made at the ends with a weakening, and the length t of the weakening section is determined by the formula: Ic-nf / LE / (Tnj; f 5/12 a = 2-b / EH, where c is the distance from the center of gravity of the weakened section to the most compressed fiber; f is the allowable amount of bending of the elements; L is the length of the element between the centers of the supports; E is the modulus of elasticity; a ,, i, J ,, 2 is the allowable bending stress, respectively, in the weakening section and in the section between the supports, defined as the difference between the calculated and axial stresses; h is the distance from the gravity of the un-attenuated section of the element up to the most compressed fiber. 2 Cp f-ly. 5 ill. §

Description

The invention relates to construction, namely to lattice metal structures.

The purpose of the invention is to improve the reliability of operation and control.

FIG. 1 shows a multi-span continuous truss (elements with weakening are highlighted in thick lines); in fig. 2 - section A — A in Fig. 1; in fig. 3 - the same, a composite element in a deformed state; in fig. 4 - section A — A in Fig. 1 (version); in fig. 5 - section B — B in Fig. 4.

The multi-span truss consists of chords 1 and a lattice 2, made of composite elements united by connecting parts. The truss has 3 main and additional intermediate 4 supports. The descending braces 5, located in the panels adjacent to the intermediate supports 4, are made with weakening at the ends, and the length of the weakening section is determined by the formula where c is the distance from the center of gravity of the weakened section to the most compressed fiber;

f is the permissible bending of the elements;

B - the length of the element between the centers of the supports;

E is the modulus of elasticity;

σ „ι, σ„ 2 — permissible bending stresses, respectively, in the area of weakening and in the area between the supports, determined as the difference between the design and axial stresses;

h is the distance from the center of gravity of the unweakened section of the element to the most compressed fiber.

The weakening of the elements in the end zones is advisable to create a clear work and to implement the bending of elements with significant rigidity, as well as to eliminate plastic deformations and fractures in the attachment points. Joints close to hinges are created in the end zones, separate elements of a composite section can deform at a free length along a half-wave of a sinusoid. Versatile curvature of elements is limited by installing clamps. In the interval between the nodes, the braces 5 are united by fixing parts 6. When compression appears in the descending braces 5, the constituent elements are bent from the plane of the truss during operation. During normal operation, the truss braces 5 are stretched. Their ultimate bending is limited by the fixing parts 6. The fixing parts can be made in the form of pivoting links. The normal operating state of the components (braces) 5 is straight. The appearance of a bend indicates the appearance of compressive forces in them and, as a consequence, a change in the supports 4 or the state of other elements of the truss. This serves as a signal to eliminate unfavorable factors (inspection, repair, etc.).

The device can be used when reinforcing spans by installing additional supports. After installing additional supports 4 under the truss, the connecting gaskets are removed from the elements of the lattice 5 of the truss, determined on the basis of the analysis of the structure's operation, and the fixing parts 6 are installed. In this case, a significant effect is achieved in comparison with the known solutions for strengthening by placing additional supports. To eliminate the negative impact from the movements of the supports in the known devices, expansion joints are used, located between the additional support and the reinforced structure.

The invention makes it possible to abandon scarce, difficult-to-manufacture parts, reduce labor costs during reinforcement, it becomes possible to control the stress-strain state of the structure.

Claims (3)

00 to Invention relates to the construction, namely to metal lattice structures. The purpose of the invention is to increase the reliability of operation and control. FIG. Figure 1 shows a multi-span indissoluble truss (elements with attenuation are indicated by thick lines); in fig. 2 shows section A-A in FIG. one; in fig. 3 - the same, the composite element in the deformed state; in fig. 4 shows section A-A in FIG. 1 (option); in fig. 5 is a section BB in FIG. 4. A multi-span truss consists of post 1 and grid 2, made of composite elements, connected by connecting parts. The farm has basic 3 and additional intermediate 4 supports. The descending braces 5, located in the 4 panels adjacent to the intermediate supports, are made with weakening at the ends, and the length of the weakening section is determined by the formula 1 where c is the distance from the center of the body of the weakened section to the most compressed fiber; f - allowable amount of bending of elements; L is the length of the element between the centers of E - the modulus of elasticity; 0 ,,,, 0.12 - allowable bending stresses, respectively, in the area of weakening and in the area between the supports, defined as the difference between the calculated and axial stresses; h is the distance from the center of gravity of the unabated section of the element to the most compressed fiber. The weakening of the elements in the end zones is expedient for creating a precise work and realizing the bending of elements with considerable rigidity, as well as for eliminating plastic deformations and fractures in the attachment points. Connections close to the hinges are created in the end zones, separate elements of the composite section can be deformed in the free length along the half-wave of the sinusoid. Miscellaneous curvature of elements is limited by the installation of latches. In the interval between the nodes, the braces 5 are integrated by the locking parts 6. When compression appears in the descending braces 5, the constituent elements bend out of the plane of the truss during operation. In normal operation, the truss braces are 5 stretched. Their ultimate bending is limited by the locking parts 6. The locking parts can be made in the form of pivot links. The normal working condition of the components (diagonals) is 5 linear. The appearance of a bend indicates the occurrence of compressive forces in them and, as a consequence, a change in supports 4 or the state of other elements of the truss. This serves as a signal for the elimination of adverse factors (inspection, repairs, etc.). The device can be used to strengthen the span structures by installing additional supports. After the additional supports 4 are installed under the truss, the lattices 5 of the truss, determined on the basis of the analysis of the structure, are removed, the connecting gaskets are removed and the fixing parts 6 are installed. In this case, a significant effect is achieved in comparison with the known solutions for reinforcement by placing additional supports. In order to eliminate the negative effect of the hiemets, the supports in the known devices, support-compensators are used, located between the additional support and the reinforced structure. The invention makes it possible to refuse deficient, complex and complicated preparation of parts, reduce labor costs during reinforcement, it becomes possible to control the stress-strain state of the structure. Claims I. Multiple-span trusses of the truss, including the elements of the composite section of the rolled sections, united by connecting details, characterized in that, in order to increase the reliability of operation and control, downstream braces located in adjacent with intermediate h1) 1 supports the panels are made at the ends with the weakening, ipii4eM length E of the weakening section is determined by the formula where c is the distance from the center of gravity of the weakened section to the most compressed fiber; f -7-K§: i: - - the amount of bending of elements is admissible; L - the length of the element between the centers of E - modulus of elasticity; Ori, a .2 is the allowable bending stress, respectively, in the area of weakening and in the area between the supports, defined as the difference between the calculated and axial stresses; h is the distance from the center of gravity of the unabated section of the element to the most compressed fiber, while the fittings are made with the possibility of providing limited deformations of the brace elements. 2. A farm according to claim 1, characterized in that the connecting parts are made in the form of pivot links. 3. A farm according to claim 1, characterized in that the fittings are made in the form of a bracket. .V five i / ha-and h - - f - - - .1 Llz.l .XP