RU174326U1 - PRE-STRESSED STEEL CONCRETE BEAM - Google Patents

Abstract

The utility model relates to the field of construction and can be used as floor beams and coatings of residential and public buildings. A useful model is aimed at increasing the strength, rigidity and material consumption of a steel-concrete beam. A prestressed steel-concrete beam includes a steel I-beam of integral or composite section, concrete monolithic, to on the inside of the I-beam shelves, ordinary transverse rods are welded on both sides of the wall with a step decreasing to the supports, and the middle transverse rods are equipped with They are tensioned and placed in plastic shells, longitudinal flexible rods are also placed in plastic shells. To increase the load-bearing capacity and rigidity of the beam after concreting the side cavities of the profile, longitudinal flexible rods are tensioned using tensioning devices located in the middle part of the beam. the beam has a high bearing capacity, rigidity and reliability, provides a reduction in material consumption, increases t schinostoykost for normal and oblique sections through prestressed concrete and compression after the acquisition of the desired strength.

Description

The utility model relates to the field of construction and can be used as floor beams of residential and public buildings.

A steel-concrete beam is known, containing a steel I-beam with stud bolts welded to the wall and concrete with which its side cavities are filled [see Eurocode 4 “Design of steel-reinforced concrete structures”, part 1-1, Minsk, 2010, p. 25, table. 5.2].

The disadvantage of this steel-concrete beam is the reduced adhesion of concrete to the side surface of the steel profile, which is ensured only by stud bolts and the absence of longitudinal rods that improve the joint work of concrete and steel profile and increase the overall bearing capacity of the composite beam.

A steel-concrete beam is known, including a steel I-beam with “P” shaped clamps welded to the walls of the profile with longitudinal rods missing under the “P” shaped clamps (see Eurocode 4 “Design of steel-reinforced concrete structures”, part 1-1, Minsk, 2010, p. 34, Fig. 6.10 (3)).

The disadvantages of such a steel-concrete beam are: the complexity of manufacturing a steel-concrete beam with a reinforcing cage. First you need to make a frame consisting of clamps and longitudinal rods, then weld the clamps to the walls. Longitudinal rods located in the upper and lower zones of the cross-section of the beam are used inefficiently, due to the lack of prestressing in them, such a beam has a high deformability.

The closest is a steel-concrete prestressed beam, including a steel I-beam, transverse and longitudinal rods, monolithic concrete, in which transverse rods are welded to the I-beam shelves on both sides of the wall, longitudinal flexible rods are prestressed due to the tension device located in the lower part of the middle transverse rods.

The disadvantage of such a prestressed beam is the ineffectiveness of the prestressing of the steel-concrete beam due to the impossibility of transferring the prestressing forces to hardened concrete, since the tensile forces are transmitted only to the steel I-beam, which is then filled with concrete and the direct compression of concrete, the main effect of the prestressed elements, does not fully occur.

The utility model is aimed at reducing material consumption, increasing rigidity and increasing the effect of prestressing, and as a consequence of the overall bearing capacity of a steel-concrete beam.

The result is achieved in that in a steel-concrete beam, including a steel profile of an integral or composite I-section, having transverse and longitudinal rods, monolithic concrete, according to a utility model, fasteners are installed in the end part of the beam, in which the ends of longitudinal prestressed reinforcing rods are fixed, ordinary transverse rods are located on both sides of the wall, in increments decreasing to the supports, and the middle transverse rods on which the thread is cut under the internal thread of the tensioner and to ltsevoy groove under the washer-closure, the lower end includes a hole rotatably and, in the upper region are provided with a torque wrench head.

The result is also achieved by the fact that the transverse rods of the middle zone with tensioners are also placed in plastic shells, moreover, the height of the tensioner shell is greater than its height by the value of the tension stroke “Δ”.

The result is also achieved by the fact that on the inner side of the transverse rods on both sides of the walls are placed in a plastic shell prestressed longitudinal rods of flexible reinforcement.

In FIG. 1 shows a prestressed steel-concrete beam, consisting of an I-beam profile of a whole or composite section with transverse rods, longitudinal reinforcement and monolithic concrete; in FIG. 2 - node A tensioner longitudinal reinforcement; in FIG. 3 - view "B" of the node "A"; in FIG. 4 - node "C" - the upper zone of the middle transverse rod with a head; in FIG. 5 - head and annular groove of the transverse middle rod; in FIG. 6 - washer latch.

The prestressed steel-concrete beam includes a steel profile 1, transverse in-line rods 2 and longitudinal rods 3, reinforcement concrete 4, middle transverse rods 5. To improve the joint work of concrete with a steel profile, the transverse rods 2 are placed on both sides of the wall, in increments of ₁ , a ₂ , ₃ , etc. with a decrease in the beam supports. At the ends of the longitudinal rods 3, fastening plate elements 7 are welded to the shelves of the steel profile 1, in which the ends of the longitudinal reinforcing rods 3 are fixed with a head 8.

The longitudinal rods 3 and the transverse middle rods 5, the tensioners 11 are placed in plastic shells 9, 6, 12, respectively, moreover, to ensure tension after hardening of concrete, the height of the plastic shell 12, the tensioner 11 is greater by the magnitude of the tension stroke "Δ".

In the factory, first perform the welding of ordinary transverse rods 2 with a step decreasing to the supports. To strengthen and align the lower edge of the upper girder belt, a washer 17 is welded. On the transverse middle rods 5 with thread 10, put on the sheath 6 and place tensioners 11 with sheath 12, the rods are inserted with the lower end into the hole 13 of the lower belt of the steel profile. In the annular grooves 15, put on the washer latch 16. Weld from one end of the beam of the fastener 7, the end of the longitudinal rod 3 with the head 8 is passed from one end through the hole in the fastener 7, put on a plastic sheath 9 and the other fastener 7, form the second head 8 and weld the fastener 7 from the other end of the beam. Monolithic concrete is made of the lateral cavities of an integral (Fig. 1) or composite I-beam. After hardening of concrete, the flexible longitudinal rods 3 are pulled, turning the head 14 of the middle rods 5 with a torque wrench. From the stresses, the fastening element 7, turning relative to the fastening point due to plastic deformation of the plate, compresses concrete 4.

The creation of prestressing by compressing concrete due to the transfer of tensile forces from the longitudinal rods to concrete according to the classical scheme increases the stiffness and bearing capacity of the steel-concrete beam.

The assembled prestressed steel-concrete beam has increased rigidity, bearing capacity and reliability, as well as reduced material consumption.

Claims (4)

1. Prestressed steel-concrete beam, including a steel I-beam of whole or composite section, filling concrete, longitudinal prestressed rods, transverse row rods and rods with tensioners, characterized in that the longitudinal prestressed rods and transverse rods of the middle zone with tensioners on both sides of the wall are placed in plastic shells, moreover, the height of the tensioner shell is greater than its height by the magnitude of the tension stroke of the longitudinal reinforcement. 2. A prestressed steel-concrete beam according to claim 1, characterized in that all ordinary transverse rods, except for the middle rods, are welded to the flanges of the I-beam on both sides of the wall with a step decreasing to the supports. 3. The prestressed steel-concrete beam according to claim 1, characterized in that the transverse rods under the tensioners, equipped with a thread at the bottom, enter the opening of the shelf with the possibility of rotation, and in the upper zone are equipped with a head for a torque wrench. 4. The prestressed steel-concrete beam according to claim 1, characterized in that the transverse rods with tensioners in the area of the upper belt of the I-beam are equipped with a washer-latch placed in the annular grooves of the rod.

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