RU88364U1 - FOUNDATION FOUNDATION BEAM - Google Patents

Abstract

Armock stone foundation beam, including a system of continuous bending sections, made by laying on an edge from an ordinary ceramic brick with three cylindrical vertically and symmetrically located holes, reinforced with a spatial reinforcing frame, characterized in that the longitudinal rods of the spatial reinforcing frame are made up of composite and grouped according to the diagrams of bending moments and lateral forces, the laying of ceramic bricks is made with a complete and dense filling of all seams and holes of chalk coarse grained plasticized multicomponent concrete.

Description

The utility model relates to the field of construction, in particular, to foundation beams and is intended to overlap the spaces between separate columnar foundations in order to absorb the load from the higher located stone walls of buildings and structures.

Closest to the utility model in technical essence are typical designs of reinforced concrete foundation beams of a trapezoidal section in brick buildings with column spacing of 6 and 12 m / Shishkin R.G. Prefabricated reinforced concrete structures of one-story industrial buildings. - M .: Stroyizdat, 1971. - 95 p. / [1] (adopted as a prototype). Their use leads to a rise in the cost of construction, requires in the case under consideration the irrational transportation of small batches of beams, increases the range of construction products and the number of their suppliers.

The essence of the utility model is to reduce the economic and material costs when building the foundations of small buildings, remote from the construction industry enterprises, located on relatively strong soils with a certain depth, possibly: permafrost, subsidence, heaving or with some other special operating conditions.

The technical result of the utility model is to improve the design of the reinforced stone foundation beam, simplify the construction technology, increase the bearing capacity of rigidity and durability.

The technical result in the implementation of the utility model is achieved by the fact that in the well-known reinforced-stone foundation beam, which includes a system of continuous bending sections, made by laying on a rib of ordinary ceramic brick with three cylindrical vertically and symmetrically located holes, reinforced by a spatial reinforcing cage, the feature is that the longitudinal the rods of the spatial reinforcing cage are made composite and grouped according to the diagrams of bending moments and transverse s l, ceramic brick masonry is made with full and dense filling of all joints and holes with fine-grained plasticized multicomponent concrete.

The reinforced stone foundation beam is a system of continuous bending sections, supported by rows of columnar foundations, made of high-quality masonry on an edge made of ordinary ceramic brick of plastic pressing with three cylindrical vertically and symmetrically located holes with marks no lower than in strength M300 and in frost resistance F50 with reinforcing spatial reinforcing frames installed inside and during masonry, the longitudinal rods of which are composite, with grouped according to the diagrams of bending moments and transverse forces, bricks are strung on them with their specific holes, and transverse reinforcement is made in the form of wire clamps as in knitted frames of reinforced concrete structures. At the same time, in the masonry, all joints and openings of the brick are completely and densely filled with fine-grained plasticized multicomponent concrete with a strength class of at least B30 and a frost resistance grade of at least F50 with a settlement mobility of a standard cone of 2-4 cm. Stiff conjugation of the longitudinal and transverse sections of the foundation beam in the corners, adjacencies and intersections, provide the establishment of all longitudinal rods of each of the mating beams to the entire thickness of the beam of the transverse direction or mutual intersection of the longitudinal rods. High-quality masonry is achieved by the device of tight joints made of fine-grained plasticized multicomponent concrete, for which the brick is used in a water-saturated state, and if necessary, it is still moistened.

Figure 1 shows a cross-section in the support area of the foundation beam section, which shows: ordered layout of bricks, longitudinal bars of working reinforcement - 1, longitudinal bars of structural reinforcement - 2, vertical clamps - 3 transverse reinforcement, horizontal clamps - 4 transverse reinforcement.

Figure 2 shows a section in the middle part of the span (equal to half) of the section of the foundation beam, which shows an orderly layout of bricks, longitudinal rods of working reinforcement - 1, longitudinal rods of structural reinforcement - 2, vertical clamps - 3 transverse reinforcement, horizontal clamps - 4 transverse reinforcement.

Information confirming the possibility of implementing a utility model. The device of the stone foundation foundation beam is carried out according to the developed assembly and detailed working drawings and according to the selected description of its technology. Work begins with the device of hard flooring on the columnar foundations erected on the level. It is more rational to start laying the armored stone foundation beam from the corner of the building and perform the most loaded or more extended section. At the beginning of this section, in certain places, they are sealed and left in the form of releases of longitudinal rods of structural reinforcement - 2 and longitudinal rods of working reinforcement - 1 section of an armor-stone foundation beam of the transverse direction. To fix the first vertical row of bricks, a hard shield with stops is installed. Next, the lower bricks of the first vertical row are installed, installed in their holes, as shown in Fig. 1, and the longitudinal rods of structural reinforcement - 2 are closed with fine-grained concrete, the same longitudinal rod of structural reinforcement - 2 is installed in the slotted bed groove of the same bricks for the formation of reinforcing bars release of longitudinal rods of structural reinforcement - 2 for laying a section of reinforced stone foundation beam of the transverse direction, while this longitudinal rod of structural reinforcement - 2 must have some curvature so that it fits well with a certain hole in the brick in the vertical row of the beam section of the transverse direction. When arranging angular conjugation of sections of the foundation beam, the first segments of the longitudinal rods of the working reinforcement - 1 and the longitudinal rods of the structural reinforcement - 2 of their spatial reinforcing cages should be small (2-3 m) for the convenience of stringing bricks on them, and in addition they should be different along the length so that with their subsequent extension the joints are located in different sections to exclude the possibility of weakening the beam in one place. Then install half vertical clamps - 3 transverse reinforcements, put on the bed half of the first row and 7 cm of the protruding lower longitudinal rods of the structural reinforcement - 2 thin layer of fine-grained concrete and install the lower half of the second row by stringing bricks on these rods, bend the vertical clamps - 3 from the corner, install three middle longitudinal rods of structural reinforcement - 2 and, spreading a layer of concrete, for the longitudinal joints install the upper half of the first vertical p the venom of bricks of the most loaded section of the foundation beam, the first middle longitudinal rod of structural reinforcement is installed - 2 in the pre-cut grooves of the first row of the same section of the beam to form a reinforcing outlet for laying the section of the beam of the transverse direction, the longitudinal rods of the working reinforcement are filled with concrete into the corresponding holes - 1, providing their support in a horizontal position, add vertical clamps - 3 transverse reinforcements, install the first grooves in pre-cut the native rod of the working reinforcement - 1 section of the beam of the transverse direction, spread a layer of concrete on the bed of the first vertical row, install the second row of the section of the beam of the first direction and then in the same way complete the laying of the angular conjugation without installing horizontal clamps - 4 transverse reinforcement, since The functions are performed by crossing longitudinal rods of working reinforcement - 1 and longitudinal rods of structural reinforcement - 2 of two sections. Next, the masonry is carried out according to the drawings of figure 1, installing vertical clamps - 3 in three rows, horizontal clamps - 4 are installed in the seams of adjacent vertical clamps - 3. Thus, the masonry lead quarters of the distance between the columnar foundations, and then perform it according to the drawings of FIG. .2 and arranging vertical clamps - 3 through six rows at half the same distance, then again at a quarter of the same distance the masonry is carried out according to the drawings of Fig. 1. Further, depending on the building plan, the masonry is continued according to the technology similar to the above and ends with the joining of longitudinal rods and bricking them in less loaded or simpler sections of the beam section.

The erection of this design is preferably carried out in warm time. The erected areas should be maintained, providing growth to the required strength of the material of the seams and sealing holes.

The widespread introduction of a utility model in the construction of these buildings will give a significant economic effect and will be an important step in the development of reinforced stone structures.

Information sources

1. Shishkin R.G. Prefabricated reinforced concrete structures of one-story industrial buildings. - M.: Stroyizdat, 1971.

Claims (1)

Armock stone foundation beam, including a system of continuous bending sections, made by laying on an edge from an ordinary ceramic brick with three cylindrical vertically and symmetrically located holes, reinforced with a spatial reinforcing frame, characterized in that the longitudinal rods of the spatial reinforcing frame are made up of composite and grouped according to the diagrams of bending moments and lateral forces, the laying of ceramic bricks is made with a complete and dense filling of all seams and holes of chalk coarse grained plasticized multicomponent concrete.