EA019161B1 - Precast concrete building units - Google Patents

Abstract

Steel-concrete construction structure comprising, at least, four vertical slabs, each consisting of a column and a square precast panel centered at the column top, wherein the pre-cast panel has a circular stepped edge and reinforcing elements passing through a pre-cast panel horizontally and perpendicular to longitudinal axes of said column and protruding beyond the edge of said pre-cast panel and a floor slab laid on, at least one stepped edge of each support panel.

Description

The invention relates to a concrete precast-monolithic panels.

In the previous invention, the applicant relied mainly on the stiffness and inflexibility of the joints between walls and floor slabs held at right angles in order to redistribute moments, which are so often excessive, over varying periods of time (to adjacent plates and floor slabs, thereby weakening moments in the plates ). This redistribution made it possible to use thinner floor slabs. The mentioned invention solved its problem, although it had limitations, as in high-rise buildings, in which the redistribution of moments from plates to walls and columns, which already had huge cumulative axial loads on walls and columns, made much thicker columns necessary, which made the panel economically and aesthetically impracticable. The same is used in large slabs for open space, which are used in shopping centers and some office buildings, in which a large space adjacent to a small space exerts strong axial loads and moments.

There were many other limitations to using precast concrete products, such as unidirectional loading (onto two opposing load-bearing walls or beams, such as in a multi-core prestressed precast product) and the inability to have a solid solid floor slab, or a flat ceiling surface, or a surface that could continue rigidly and continuously in both its horizontal directions; thus, there was a need for a panel off the shelf that could do all this; panels that fit almost anywhere (calculated for this class of load); panels in which the structure and wiring can be built later, without damaging the panel or any adjacent panels in which large openings on one side, or even a garage with an open space, or a shopping center with standard panel sizes will be constructed at high speed and by ease. Since the rooms have four sides, thus, if the distribution is done on all four sides, the share of each side will be about one-fourth the weight and even less for the moments (since redistributing to adjacent panels will even further reduce the moments). From the above, a need arose for a new system of precast concrete products, a system with thinner plates, columns and walls, a system that will redistribute stresses on all four sides and not degrade (increase) moments in the walls and columns.

The present invention relates to a high-rise building / multi-storey buildings and large open spaces that contain heavy load-bearing heavy walls (in which new prefabricated monolithic panels also provide shear force obtained by other methods). The invention is so well used that it is not necessary to have counterweights on each side of columns / walls, and distributes the loads and moments over all four walls, rather than two walls, or beams, such as in a hollow wall, which, like this new system, has advantages in the speed of erection of the assembled product, but in this innovation the rigid solid monolithic front surface of the ceiling is made with an even smaller plate thickness and one size suitable for all panels, explaining the need for several sizes, all It is achieved by distributing the weight over all four panels and redistributing moments beyond the slab across all four adjacent panels, since the overlap acts as one monolithic rigid solid slab, flexibly attached to the downstream walls and columns, in order not to transfer them additional moments from upstream plate. This system reduces the weight of the slabs and, thus, the weight of the building and its foundation, especially in high-rise, where the slab thickness and weight can accumulate. You can add one extra floor for every about twenty, from the saved weight and height.

It is a system of prefabricated monolithic concrete products with a prefab panel having a T-shaped cross section that forms a room when two such panels are connected by means of an intermediate monolithic (in-place cast) concrete section. The slab is connected by means of a flexible reinforcement to the wall, which is located in the middle under the slab. Hollow centered posts pierce the panel from its base to the top of the slab; when aligned with panels at the top and bottom, filled with reinforcement that runs continuously from the base to the roof, then concrete is poured into it; solid continuous column is formed without interruption (breaks).

This three-dimensional panel is used to create buildings that are essentially horizontal planes (floor slabs) permeated with vertical walls (or columns). All planes in their respective two dimensions are made rigid, inflexible; penetrated by planes at right angles to them at the points / lines of intersection of the planes, each plane continues further free from the moments of the intersecting plane, since the connection between the two planes is a hinged joint, which only holds down horizontal and, thus, vertical movements. The crossing plane, since the plates rest on the walls / columns, does not transfer points to vertical elements or does not receive points from them, a large building is formed using a one-dimensional small precast panel from the shelf, which is suitable in almost all cases. These panels ensure continuity due to their rigidity by redistributing and transferring a part of the moments to adjacent plates on each side of the two forming panels.

- 1,019,161

In the central part of the room, which is molded in place, reinforcing bars pass perpendicular to two panels, overlapping reinforcing bars protruding from laminated panels on each side, reinforcing bars also running parallel to the walls of the panel and proceeding continuously to adjacent panels on each side. This feature changes the system, allowing it to redistribute moments across all four adjacent panels, not just two, since the slab is transformed into a monolithic hard surface across the four borders of the room, which can redistribute moments across all four adjacent plates to weaken the moments. Weight is also distributed across all four sides, reducing shear. Since there is a flexible connection of moments between slabs and walls / columns, the moment is not transmitted to the walls or columns, which is an advantage in high-rise buildings in which axial loads are already excessive. The same is true for large plates, which can attach significant moments to the columns, if the connection between the plate and the column is very rigid; these columns are preferably made continuous in this system from the bottom to the roof. Thus, the plates and columns are reduced in size when using this new system. A square step-down plate with protruding reinforcement and a column centered under it with at least a part of its steel frame is the second panel placed here, where four such panels are placed, each in the corner of the room and as the previous panel, the reinforcement passes in both horizontal directions, also blocking the protruding reinforcement of the panels, and passes continuously between the panels (also after placing the formwork to support the reinforcement and pour the concrete in place to connect the four corners, creating a room Atu also with moments redistributed across adjacent plates on all four sides to help reduce stress). The third and last panel is a step-down panel, similar to the first panel, with protruding reinforcing bars extending for about 0.5 m at regular intervals along the longer sides of the panel, but this panel has a solid beam, cast with and under the slab. This panel functions in the same way as the previous two, since the connecting central part is molded in place, however this panel is used where large open spaces are required on one side of the room.

The invention is illustrated in the drawings, where the beam under the slab in the beam-slab connection is cast monolithically with the slab, passing along the length of the slab, if not further.

FIG. one.

A square horizontal panel, stepwise decreasing by half its thickness at a distance of about 10 cm from all four edges, is reinforced with reinforcing rods extending horizontally and in parallel through the slab and projecting approximately 0.5 m from all four sides, in vertical pairs close to the upper ones and the bottom surfaces of the slab. The hollow column is centered under the slab by means of a flexible hinge with the panel above. The steel frame in the middle of the column is filled with concrete or on-site or is cast with the outer shell of the column at the factory.

FIG. 2

- Reinforcing reinforcement rod passing through the short side of the slab at regular intervals, protruding approximately 0.5 m on each side.

- One of several hollow pillars piercing both the panel wall and the panel plate centered in the wall.

- Concave extreme channel on each side of the panel, passing vertically along the entire height of the wall.

- Non-rigid reinforcement between plate and wall.

FIG. 3

- Steel reinforcing bars, which pass continuously only through the internal surface of the slab of the composite panel, projecting approximately 50 cm on each side as one rod or in a set of two, one layer on top of the other.

- Hollow pillars running continuously through the entire slab from top to bottom.

- Concave ends on each side of the wall panel.

- Steel reinforcement bars that pass continuously through hollow pillars provided in panels.

- Conduits on each side of the wall panels, each passing in two layers of approximately 30 cm and 1 m from the bottom of the panel.

- Hole formed by the alignment of two adjacent panels, stepwise lowering the top half of the slab at the edges of the wall panels.

- Flexible conduit connecting two adjacent panels. It can also be used to lead wiring to the middle of the room, the other side of the room, the floor below or the floor above, as well as to the rooms on either side of the panel.

- Non-rigid reinforcement joint between two planes - plate and wall.

FIG. four.

Precast panel, typical slab with a continuous through-passing reinforcement

- 2019161 measured at 50 cm on each side.

The T-shaped collection panel in its section consists of an elongated slab, which is reduced by half in thickness by 10 cm on its four sides, with reinforcing bars passing through it and protruding approximately 50 cm along the longer sides of the rectangle centered under it and attached to it by means of a flexible reinforcement, is a wall that extends along the length of the slab. There are pillars passing vertically and centered along the axes of the walls at regular intervals. The two edges of the wall are concave to tie the walls on each side or add a column, if necessary, or a conduit post. The plates are rigid, resting on the walls / columns, by virtue of which there is a freedom of continuity of movement of the moment in the plates, which are still pivotally attached to the wall below. Consequently, this system is ideal for a high-rise building and provides fast erection, light weight and longer spans with a lower plate thickness, but a solid, rigid plate can transfer wind and seismic loads to the central frame of the communication system wall. Walls and columns are also best used by this system in high-rise buildings, since the columns do not carry additional moments in the slab from each floor, therefore, there is no need to increase them unnecessarily, since the plates are solid and rigid, capable of transferring transverse forces to the building frame, which is designed to withstand it. Solid steel columns from the foundation to the roof are an additional feature that helps reduce the size of the wall / columns, since the columns are not attached at the top and at the base of each floor, but preferably run as one solid column from the foundation to the roof. These preferred features are preferably used in any slab that should be large with smaller columns, such as shopping centers, theaters, office buildings. PVC cable conduits (polyvinyl chloride) run horizontally on each side of the wall at a distance of about 30 and 110 cm from the bottom edge in the concave channels on each side, they are used for IT and electrical cables.

Claims (3)

1. Steel-reinforced concrete building structure containing at least four vertical supports, each support consisting of a vertical column (2) having a steel frame (6) in the middle, and a square precast horizontal panel (3) centered at the top of the column (2), moreover, the panel (3) has a stepped edge (4) on all four sides at its apex, from which steel reinforcing bars (5) protrude to attach horizontal plates to the panels to form a continuous horizontal surface, and steel reinforcing bars The rod rods (5) are arranged in two groups, each group consisting of horizontal and parallel steel rods, while the direction of the rods in each group is perpendicular to the direction of the rods in another group, characterized in that the building structure contains at least a central part a plate cast in place between the panels (3) of at least four vertical supports (2); the stepped edge (4) has lower and upper vertical shelves, while the upper vertical shelf is located at a horizontal distance of about 10 cm from the lower vertical shelf and closer to the center of the panel, on all four sides of the panel, while both shelves have a height corresponding to approximately half the thickness of the panel; groups of reinforcing bars arranged in vertical pairs extend approximately 50 cm around the perimeter of the panel (3) on all four sides of the panel (3), respectively, from the upper and lower vertical flanges of the edge (4), for distributing moments to all at least four adjacent panels (3), cast in place of the central part of the plate. 2. Steel-reinforced concrete building construction according to claim 1, characterized in that the steel frame (6) in the middle of the column (2) is poured with concrete. 3. Steel-reinforced concrete building construction according to claim 1 or 2, characterized in that the column (2) consists of an external concrete shell (7). 4. The method of erecting a steel-reinforced concrete building structure according to claims 1 to 3 by installing at least four vertical supports, each support consisting of a vertical column (2) having a steel frame (6) in the middle and a square prefabricated horizontal panel (3) centered on the top of the column (2), and the panel (3) has a stepped edge (4) on all four sides at its apex, from which steel reinforcing bars (5) protrude to connect the horizontal plates to the panels (3) to form a continuous horizontal by surfaces, the steel reinforcing bars (5) being arranged in two groups, each group consisting of horizontal and parallel steel bars, the direction of the bars in each group being perpendicular to the direction of the bars in another group, characterized in that at least the central part the plates are cast in place between the panels of at least four vertical supports; stepped edge (4) is performed with the lower and upper vertical shelves, while the top - 3 019161 a new vertical shelf is placed at a horizontal distance of about 10 cm from the lower vertical shelf and closer to the center of the panel, on all four sides of the panel, with both shelves having a height corresponding to approximately half the thickness of the panel; groups of reinforcing bars are installed in vertical pairs protruding approximately 50 cm around the perimeter of the panel (3) on all four sides of the panel (3), respectively, on the upper and lower vertical flanges of the edge (4), for distributing moments on all at least four adjacent panels cast on the center of the slab.