CZ438599A3 - Grate floor of lightweight concrete brickwork - Google Patents

Abstract

The new construction system of grilled lightweight concrete masonry ceiling solves the problem of casting flat slabs, roof slabs, stairs and similar structures. It is rational, efficient in casting, it has excellent conditions of load bearing, temperature insulation properties, moisture protection and fire resistance. The new system consists of the following elements: prefabricated steel-concrete girder (1), prefabricated lightweight concrete or micro-concrete lower threshold (2), prefabricated lightweight ceiling block (3), single-layered or three-layered, lateral ribs (4), reinforced and made of lighweight concrete or micro-concrete, prefabricated lightweight upper threshold (5), thin mortar layer (6) made of cement or similar materials; all these elements, by their forms and dimensions, form a compatible system. The structure can be cast manually without any supporting because the structure is selfbearing. The structure is of a grill type with a hidden compressive slab. Due to the prefabrication the structure is camber. The ceiling block is produced as a final structural element. The final ceiling is covered by a thin mortar layer. The adaptability of the system to different forms of houses and buildings, by using a few types a precast elements, contributes to its rationality and wide applicability. The regular form of the elements makes possible the application of different parts of buildings of various forms; thus, architects and engineers have a greater creative freedom in, the design of houses and buildings.

Description

Slatted brick ceiling made of lightweight concrete

TECHNICAL FIELD FIELD j is well-defined subclasses in accordance with International Patent Classification E04B 1/00 and ^F E04B 2/00 international patent classification, which include general structures built by using new design and construction methods.

Technical issue

The slatted brick ceiling made of lightweight concrete solves the problem of assembling ceiling slabs, roof slabs, stairs and similar constructions. The structure can be mounted manually without any support, since the structure is self-supporting due to assembly. The construction is of the slatted type with concealed

- pressure plate. As a result of prefabrication, the structure is domed. The ceiling block is manufactured as a finite, structural element. The final ceiling is covered with a thin layer of mortar. The adaptability of the system to different forms of houses and buildings, using several types of pre-cast elements, promotes their rationality and wide applicability.

BACKGROUND OF THE INVENTION

Existing lightweight concrete systems that address, to some extent, the technical task mentioned are (1) a mixed brick system

Ytong, used in Portugal: prefabricated board system of twenty European countries, (3) Siporex system similar (2) Italgas board system similar

There are no similar solutions to the construction industry, therefore, Israel and Turkey, (2) Ytong, used in more than prefabricated board system (Europe), (4) prefabricated system (2) (Europe).

the solution according to the invention in: e all previous systems ft ftft ft ft ftft ft ft ftftft ftft ftft ftftft ftft ·· ·· <

were based on the significant contribution of lightweight concrete in the transfer of internal forces, stress.

In accordance with the principle used in this patent, stresses are transmitted by the reinforcement while lightweight concrete or micro-concrete has a minor role.

SUMMARY OF THE INVENTION

The main feature of this patent is the application of the principle of complete reinforcement of lightweight concrete or micro-concrete into prefabricated beams and transverse ribs of a slatted brick ceiling structure.

This principle allows almost complete transfer of compressive, tensile and shear stresses to the reinforcement.

Thus, the grate elements carry the total force, the ceiling block may be a component that carries local loads without a commonly used pressure plate.

The thin mortar layer poured onto the block and the grate system makes the system a compact construction.

Due to the low weight of the structure and the high load-bearing capacity of the beam, the structures do not need to be supported during assembly. The vaulting of the prefabricated beam follows this principle.

Therefore, the lightweight concrete body becomes a secondary structural medium for local and overall stabilization and assumes the role of anti-corrosion, anti-heat, noise and moisture protection.

BRIEF DESCRIPTION OF THE DRAWINGS

The drawings show a new lightweight concrete slatted ceiling system. Each figure illustrates one possible use of the system and does not limit the rights contained in the claims.

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Giant. 1 shows cross-sections of prefabricated beams of type D; FIG. 2 shows views of beams of type D;

Fig. 3 is a cross-sectional view of the ceiling structure, showing the ceiling structure with individual beams at the top and Fig. 4 showing a longitudinal section of the ceiling structure; Fig. 5 shows cross-sections Fig. 6 shows an axonometric view of the lower threshold and the upper threshold.

DETAILED DESCRIPTION OF THE INVENTION Pre-fabricated bottom sill

The new slatted brick ceiling system made of lightweight concrete, as shown in Figures 1 to 5, consists of the following elements of prefabricated steel-concrete beam prefabricated with lightweight concrete or ^: micro-concrete, lightweight single or three-layer ceiling block 3, cross ribs, reinforced and fabricated made of lightweight concrete or micro-concrete 4, prefabricated lightweight upper threshold 5, a thin mortar layer 6 of cement or the like; all of which form and size form a compatible system.

The prefabricated self-supporting beam á shows in Figs. 1 and 2 that the beam D is cast with partially welded steel reinforcement, whose bars are selected according to load-bearing conditions and stability, which, if necessary, is protected by a coating. The reinforcing bar consists of quadruple trusses 1.3 and 1.4 whose diagonal bars, depending on the spans, are cast in X, V or N shape, with reinforcements reinforced by the added bars 1.6 and 1.5 in the upper and lower zones, which is not mandatory; the bottom surface 1.1 and the body 1.2 are made of lightweight concrete whose compressive strength reaches 3.0 MPa or of micro-concrete made of fine sand of less than 8.0 mm, with a lower curved edge in the shape of a quadratic parabola, or a similar shape and with a buckle of 1/750 <Δ <1/50, where 1 is the span of the beam.

Recommended dimensions are: span 1 <6.5 m for H = 20 cm, span 1 <12.0 m for H = 25 cm. The lower concrete zone has t = 3 cm, d = 9.0 cm, the upper zone dl = 5.0 cm, h1 = 5.0 cm, node spacing k = 20 cm. The recommended spacing of beams B is 68 to 79 cm and the spacing of the transverse ribs is 79 to 129 cm.

The prefabricated lower sill 5 shown in FIG. 5 has the shape of an elongated parallelepiped or a similar shape which is cast from lightweight concrete or micro-concrete and reinforced by at least one bar 2.1 whose edges protrude out of the parallelepiped and serve as a sill support on the beam.

Recommended dimensions are: span 1 = B-d, t =. 3 cm, b = 3 to 5 cm. ............ '´ ..... I' .....

3, 4 and 5. Its dimensions and reinforcing bars are selected according to: ceiling load-bearing capacity, thermal protection, moisture resistance and fire resistance, and its rods are protected by coating if necessary. The first lightweight layer 3.1 is made of lightweight concrete with a density of less than 1500 kg / m ³ and a compressive strength of 2 MPa, reinforced with wires or a welded wire cloth 3.4 having a slot 3.5 at the edge. The second non-load-bearing layer 3.2 is made of expanded polystyrene, mineral wool or similar super-lightweight material or lightweight concrete with a density of less than 1000 kg / m ³ . The third layer 3.3 is made of lightweight concrete, which is not mandatory.

Recommended dimensions are: length (B-dl) 45 to 65 cm, depth H 12 to 30 cm, belt width 20 to 50 cm.

'4 4 ···· •• 44 44

The lightweight monolayer block 3 is shown in Figures 3, 4 and 5. It is made of light aerated concrete, foam concrete, polystyrene foam concrete or similar materials whose specific gravity is less than 900 kg / m ³ and the compressive strength reaches 2. MPa, the tensile bending strength reaches 0.2 MPa. It is designed as a parallelepiped with a notch on the edge

3.5 of quadratic or similar shape. The recommended dimensions are similar to the three-layer block.

The transverse rib 4 is shown in FIG. 4. Its reinforcing bars are in the lower zone 4.2, the reinforcing bars in the upper zone 4.3 which are not necessary; It is cast at the site of assembly of lightweight concrete or micro-concrete in the space formed between the threshold and the ceiling block, which together with the beam 1 form a grid structure resistant to loads acting in and out of the plane, especially seismic loads.

The recommended belt width is b = 3 to 5 cm, the depth (H-t) is 10 to 27 cm.

One possible way of making the expanded body of the beam 1, the ceiling block 3 and the transverse rib 6 is to use an additive-based lightweight concrete made of expanded polystyrene. If the lightweight concrete is made of lightweight expanded polystyrene, then the density should be higher than 800 kg / m ³ for structural elements or elements exposed to any type of fire load.

Industrial applicability

The use of this patent in industry is obvious. The proposed lightweight brick masonry ceiling is applicable in practice to a new way of mounting various structures such as ceiling slabs, roof slabs, stair structures and the like, based on the prefabrication and joining system of this patent.

Claims (4)

PATENT CLAIMS 1.Relayed lightweight concrete masonry ceiling, lightweight concrete composite structure with steel reinforcement, high prefabrication level, including steel-concrete beam (1), lower sill (2), structural ceiling block (3), transverse ribs (4), made of a lightweight reinforced concrete or micro-concrete, a lightweight upper threshold (5), a thin mortar layer (6) made of cement or similar materials; all these elements being formed in at least one step, characterized in that the steel-concrete beam (1) consists of a concrete body (1.2) and a prefabricated self-supporting beam (D) made of two double trusses (1.3) and (1.4), pre-fabricated of welded reinforcing bars placed one above the other one half the distance of the truss step, with diagonal bars, depending on the span, in the form of X, V or N, and further comprising additional bars (1.6) and (1.5), and a lower curved concrete track (1.1) with an elevation Δ, where 1 is 750 <Δ / 1 <Ι / 50 and where the lower curved concrete track (1.1) and the concrete body (1.2) are made of lightweight concrete with a compressive strength of 3, 0 MPa, or of micro-concrete made of fine sand with a size of less than 8,0 mm, the lower sill (2) having the shape of an elongated parallelepiped or a similar shape made of lightweight concrete or micro-concrete and is reinforced by at least one bar (2.1) whose edges protrude out of the parallelepiped and serve as a sill support on the steel-concrete beam (1), the ceiling block (3) being a prefabricated, single-layer member made of light aerated concrete expanded polystyrene concrete or similar cellular concrete with a specific gravity of less than 900 kg / m ³ , a compressive strength of 2 MPa, a tensile bending strength of 0,2 MPa and formed as a homogeneous parallelepiped with a quadratic or similar shape,. · ·· ·· ·· ··. •:. ::: • jj j: Where this can be provided with an upper threshold (5) made as a prefabricated lightweight member. The lightweight concrete slatted brick ceiling according to claim 1, characterized in that the structure is self-supporting during casting due to the use of a pre-cast self-supporting beam (D1) acting as a support element. Slatted lightweight concrete ceiling according to claim 1 and 2, characterized in that the structural ceiling block (3) is pre-fabricated as a three-layer member, wherein the first layer (3.1) is made of lightweight concrete with a specific gravity of less than 1500 kg. / m ³ and a compressive strength of 2 Mpa, reinforced with wire or welded wire cloth (3.4), the second non-bearing layer (3.2) being made of expanded polystyrene, mineral wool or super lightweight material or lightweight concrete with a specific gravity of less than 1000 kg / m ³ and the third layer (3.3) is made of lightweight concrete. ⁴ 4. Method of casting a reinforcing frame of a prefabricated beam. (D) according to claim 1, characterized in that the prefabricated reinforced trusses (1.3) and (1.4) are placed one above the other and are spaced by 1/2 of the truss step; add additional bars to the upper zone /1.6), whereupon the whole frame is compressed longitudinally so that the lower end reaches the correct depth and the diagonal bars of the truss (1.3) compress the upper upper end of the truss (1.4) while the diagonal bars of the truss ) compresses the additional reinforcing bars (1.6) whereupon the additional bars in the upper zone (1.6) and the lower zone may be cast.