RU14232U1 - REINFORCED CONCRETE FARM - Google Patents

Abstract

Reinforced concrete truss consisting of two parallel belts, racks and braces with pre-stretched high-strength reinforcement in the lower zone, characterized in that the reinforcing frame of the upper belt is made of pre-compressed high-strength steel.

Description

REINFORCED CONCRETE FARM

The invention relates to construction and can be used as a supporting structure and covering buildings.

Typical reinforced concrete trusses are known - segmented, polygonal, triangular, with parallel belts, in the lower belts of which are pre-stretched reinforcement (see Prefabricated reinforced concrete prestressed segment trusses for covering buildings with spans 18; 24 and 30 m. - PC-01129.- Series Vyp.1.M .: TsITP, 1964)

Reinforced concrete trusses are known in which a pre-stretched high-strength reinforcement is located in the lower belt, and a reinforced cage made of ordinary reinforcement of the A-Sh class is located in the compressed belt (see Baykov V.M., Sigalov E.E. Reinforced concrete structures. General course .- M .: Stroyizdat, 1991.- S. 413-424 and 725-734).

The disadvantage of such designs is that in the compressed belt, not high-strength reinforcement of class A-III (or lower) is used, because stresses in the reinforcement cannot exceed 400 MPa due to the limited compressibility of concrete.

The essence of the invention lies in the fact that in a reinforced concrete farm consisting of two parallel belts, racks and braces with a pre-stretched high-strength reinforcement in the lower zone, the upper belt is additionally made using a reinforcing frame made of pre-compressed high-strength steel.

The invention is illustrated in the drawing, where in FIG. 1 shows a General view of the proposed farm with pre-stretching E 04 with 3/20

with reinforced reinforcement in the lower belt and with a pre-compressed frame of high-strength reinforcement in the upper, Fig. 2 shows the formwork of the upper truss belt (concreted flat) with the framework installed in it, and in Fig. 3, a longitudinal section along A-A on figure 2.

Pre-stretched reinforcement 1 can be made of any high-strength steel - rod, wire, rope, and the reinforcing frame 2 of the upper belt is made of longitudinal high-strength working rods 3 and closed clamps of two types - ordinary 4 and with protruding ends 5. Form - formwork consists of the bottom 6, the side walls 7 and the steel strips 8 attached to them, arranged in increments equal to the distance between the clamp; 5. The latter, with their protruding ends, abut the bottom 6, the side walls 7 and the strips 8, which ensures carcass stability for pre-compression.

The preliminary compression of the longitudinal high-strength rods 3 is carried out simultaneously through steel plates installed in the ends of the upper truss belt. The compression force from the jack is transmitted to these plates, which leads to the simultaneous preliminary compression of all four longitudinal rods. After this, the farm is concreted.

When the concrete reaches sufficient strength, the rods 3 are released from the anchor devices and the prestress is transferred from the reinforcement to the concrete, as a result of which the reinforcing rods of the upper belt are pre-compressed, and the concrete is pre-stretched. This will lead to the fact that when loading the truss with an external load in the longitudinal rods of the upper belt, the ultimate stresses increase by the amount of preliminary compression

 z

asp, i.e. become equal to RSC + crsp. As a result, it becomes possible to efficiently use high-strength steel for reinforcing the upper belt, which will significantly reduce the consumption of steel. Steel consumption is reduced by (RSC + crsp) / RSC times.

We give an example. In a reinforced concrete farm with parallel belts with a span of 24 m, considered in the aforementioned book by V. Baykov and Sigalova E.E. (prototype) consumption of reinforcement class A-W in the upper zone amounted to 298.692 kg The force perceived by this reinforcement (4 0 25 A-W) is equal to AS RS 19.63 3650 71649, 5 kg 716, 495 kN.

When replacing valves of class A-III to class A-VI and its preliminary compression to asp 400 MPa, the ultimate stress will be RSC + crsp 400 + 400 800 MPa. In this case, the necessary cross-section of the reinforcement will decrease to AS 71649.5 / 8000 8.956 cm, i.e. more than 2 times. If we take with reserve the corresponding reinforcement of the upper belt - 4 0 18 A-VI (AS 10.18 cm), then the steel consumption will be 24 4 1.998 191.81 kg, i.e. will decrease by 36%.

In addition, pre-compression of the reinforcement of the upper belt will lead to the bending of the truss, as a result of which the total deflection will decrease and the trash will increase; the foreign resistance of the lower belt will also increase.

Claims (1)

Reinforced concrete truss consisting of two parallel belts, racks and braces with pre-stretched high-strength reinforcement in the lower zone, characterized in that the reinforcing frame of the upper belt is made of pre-compressed high-strength steel.