MD678Z - Precast and cast-in-situ floor - Google Patents

Abstract

The invention relates to the construction, especially to partially prefabricated floors, and can be used to install the floors of buildings and constructions with destination and number of different floors. The partially prefabricated floor contains a matrix of reinforced concrete and some light elements of a lower lost formwork, on which is placed a reinforcing mesh (4) and a concrete layer (5). On the perimeter the floor contains a lost lateral formwork. The element of the lower lost formwork is executed in the form of a block with holes (1), two sides of which are executed vertically, and the other two - with an inner slope. The base of the block (1) is provided with flanges, protruding out of the block dimensions (1) from the sloping parts, and on the flanges, in the games between blocks (1), when they are arranged some reinforcement boxes (3) are located.

Description

The invention relates to construction, in particular to partially prefabricated floors, and can be used in the installation of floors in buildings and structures with various purposes and numbers of floors.

A partially prefabricated floor is known, which consists of reinforced concrete beams with reinforcement cages. Box-shaped filler elements are placed on the beams, and a reinforcing mesh and a concrete layer are placed on top of them [1].

The disadvantages of the known floor are the large amount of work involved in its installation and its increased weight.

Also known is a floor, which consists of concrete beams with open reinforcement cages. Between the beams are placed filling elements in the form of hollow blocks. On the blocks are placed a reinforcing mesh and a layer of concrete [2].

The disadvantages of the known floor are the increased self-weight due to the presence of the beam, as well as the need to use lifting equipment.

The closest solution is a partially prefabricated floor, which consists of concrete beams with protruding reinforcement cages, which are installed on the reinforced concrete base frame of the building. Between the beams, close to each other, filling elements made in the form of hollow blocks are placed, forming a lower lost formwork. Reinforcement mesh is placed on the blocks, and on top of the entire structure is poured with a layer of concrete. After the concrete hardens, a lightweight reinforced concrete floor slab is formed [3].

The disadvantage of the known slab is the presence of a beam, on which the blocks are placed. The beam is quite complicated to manufacture and, therefore, expensive, and it is also difficult to transport and store it without damage. The sufficiently large weight of the beam (one linear meter of the beam weighs about 20 kg) requires the use of lifting devices for its lifting and installation.

The problem solved by the invention consists in reducing the dead weight of the floor, increasing its load-bearing capacity and earthquake resistance, as well as reducing material and labor costs for installing the floor.

The problem is solved by the fact that the partially prefabricated floor contains a reinforced concrete matrix and some lightweight elements of a lower permanent formwork, on which a reinforcement mesh and a concrete layer are placed. On the perimeter, the floor contains a lateral permanent formwork. The element of the lower permanent formwork is made in the form of a block with holes, two side parts of which are made vertical, and the other two - with an internal slope. At the same time, the base of the block is equipped with some flanges, protruding outside the dimensions of the block from the parts made with a slope, and on the flanges, in the gaps between the blocks, when arranging them, some reinforcement casings are placed.

The lateral formwork can be made of L-shaped elements.

The block can be made open on the vertical sides with the possibility of forming channels at the joints for mounting communications.

The floor may contain a beam girder, which consists of U-shaped blocks that are fixed to the corners of the building at a 45° angle, forming a channel in which reinforcement is placed.

In the part subject to tension, the floor may contain spiral-shaped reinforcement, executed as separate bars, located at the bottom of the gap between the blocks.

The lateral and lower lost formwork elements can be made of macroporous concrete based on crushed limestone with a backfill density of no more than 1.25 t/m3.

The execution of hollow blocks with two sides with an internal slope and equipped with flanges, which determine the distance between the blocks of neighboring lines when arranging them, allows to reduce the weight of the floor and increase its load-bearing capacity.

The blocks arranged close to each other thus form the lower permanent formwork, and along the perimeter the lateral permanent formwork is mounted, assembled from L-shaped elements.

When arranging, in the gaps between the blocks, on their flanges are placed reinforcement casings, which work in tension. Such reinforcement casings are placed in the gap between the side and bottom formwork. The reinforcement arms connect with the reinforcement of the columns (not shown in the figure), on which the floor is installed. This allows to sufficiently increase the resistance of the floor in tension and to improve its bearing capacity.

Reinforcing mesh is placed on the hollow blocks, which acts as a compressive force and prevents the concrete from cracking as it hardens. It is also connected to the column reinforcement.

The reinforcement cages are made of the same welded mesh as the reinforcement mesh placed on the blocks.

The concrete monolithizes the entire construction into a lightweight, one-way ribbed slab, which forms a seismic disk and works in conjunction with the columns.

If it is necessary to obtain a floor with increased load-bearing capacity on the walls along the perimeter, before installing the side formwork, a level of U-shaped blocks is placed, which are fixed in the corners of the building at an angle of 45°, additionally forming a beam belt. The reinforcement is placed in the formed channel and it is joined with the column reinforcement.

A higher load-bearing capacity of the floor is obtained when the part subject to tension is additionally reinforced with spiral-shaped reinforcement, made as separate bars (for example, according to the invention, disclosed in MD s 2012 0091, 2012.12.06).

A block, open on one or two vertical sides, can be used as an element of the lower lost formwork. The channels formed by the blocks, open on two sides, can be used for the placement of electrical and sanitary communications, or can be filled with acoustic and thermal insulation material.

The technical result consists in reducing the floor's own weight, increasing its load-bearing capacity, reducing material consumption and workload.

The invention is explained by the drawings in Fig. 1-2, which represent:

- fig.1, partially prefabricated floor, general view;

- Fig. 2, partially prefabricated floor, with a beam flange, which consists of U-shaped blocks and is additionally reinforced with spiral reinforcement.

The partially prefabricated floor consists of hollow blocks 1 (lower permanent formwork) and L-shaped elements 2 (lateral permanent formwork), between which reinforcement cages 3 are placed. A reinforcing mesh 4 is placed on the hollow blocks 1. The entire structure is monolithically cast with a layer of concrete 5. Along the perimeter, before the installation of the lateral formwork, a level of U-shaped blocks 6 can be placed with the formation of a channel, in which the reinforcement 7 is placed. In the part of the floor that extends additionally, the spiral reinforcement 8 is placed, made as separate bars.

The partially prefabricated floor is installed in the following way.

Telescopic poles 9 are installed in accordance with the project and T-shaped bars 10 are mounted on them. Using the nuts included in the set of telescopic poles 9, the support surfaces of the T-shaped bars 10 are leveled in a single plane, checking the plane with a hydraulic leveling device or other measuring device.

The blocks with 1 holes on land are placed with the vertical sides open towards each other without any gaps. The second line is placed in close contact with the first line and so on, until a continuous floor is formed.

Along the perimeter of the building, the lateral formwork of the floor made of 2 L-shaped elements is mounted on the mortar.

In the gaps between the hollow blocks 1, reinforcement casings 3 are placed on the flanges of their bases. The type of welded mesh from which they are made is determined by the length of the opening and the calculated operating load.

Along the perimeter on the flanges of the bases of the L-shaped elements 2, reinforcement casings 3 are also placed. The reinforcement casings 3 of the formwork lost laterally and below are joined to each other and to the column reinforcement (not shown in the figure).

Then the reinforcement mesh 4 is placed and it is also joined to the column reinforcement.

After this, the concrete is placed 5.

After the concrete reaches 70% of the design strength, the telescopic columns 9 and the T-shaped bars 10 are dismantled.

The presented invention is significantly cheaper than known solutions due to the reduction in the amount of metal and the lack of welding work inevitable in the manufacture of support beam trusses.

The formwork elements are also not expensive, since their production involves the use of crushed limestone instead of expensive clay bricks, while minimizing the amount of binder.

Since the formwork elements are made of macroporous concrete, high adhesion of the element surfaces to the concrete is ensured. At the same time, the formwork does not weigh down the floor, but works together with the floor concrete.

Also, due to this, the adhesion of the putty layer to the formwork surface is higher, which prevents it from cracking if the painting mesh is not used.

Lifting equipment is not required when installing the floor, as there are no elements heavier than 12 kg in the construction.

The load-bearing capacity of the floor is higher than in known solutions, and its own weight is lower, which is very important for construction in regions with seismic risk, as well as on soils prone to landslides.

1. SU 537173 A1 1976.11.30

2. DE 3045663 A1 1982.06.24

3. DE 10050475 A1 2001.04.26

Claims (6)

1. Partially prefabricated floor, which contains a reinforced concrete matrix and some lightweight elements of a lower permanent formwork, on which a reinforcement mesh (4) and a concrete layer (5) are placed, characterized in that it contains a lateral permanent formwork on the perimeter; the element of the lower permanent formwork is made in the form of a block with holes (1), two side parts of which are made vertical, and the other two - with an internal slope, at the same time the base of the block (1) is equipped with some flanges, protruding outside the dimensions of the block (1) from the parts made with a slope, and on the flanges, in the gaps between the blocks (1), when arranging them, some reinforcement casings (3) are placed. 2. Partially prefabricated floor according to claim 1, characterized in that the lateral formwork is made of L-shaped elements (2). 3. Partially prefabricated floor, according to claim 1, characterized in that the block (1) is made open from the vertical sides with the possibility of forming channels at the joint for mounting communications. 4. Partially prefabricated floor, according to claim 1, characterized in that it contains a beam belt, which consists of U-shaped blocks (6), which are fixed in the corners of the building at an angle of 45°, with the formation of a channel, in which reinforcement (7) is placed. 5. Partially prefabricated floor according to claim 1, characterized in that it contains, in the part subjected to tension, spiral-shaped reinforcement (8), made as separate bars, located in the lower part of the gap between the blocks (1). 6. Partially prefabricated floor, according to claims 1 and 2, characterized in that the lateral and lower lost formwork elements are made of macroporous concrete based on crushed limestone with a backfill density of at most 1.25 t/m3.