NL8303395A - ARMED STRIP OF BRICK AND CONCRETE. - Google Patents

Description

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EdB / JG / 60.90592

JUWD ENGINEERING GubH ZiegeIMttenstr. 42 6556 WSllstein BED

ARMED CARRIER OF BRICK AND EETCN.

The invention relates to a reinforced supporting beam of brick and concrete, which comprises a number of brick shells in cross-section U- or O-shape, arranged in a line in order to form an elongated hollow space, the hollow space the concrete and the metal reinforcement. picks up.

Reinforced brick and concrete supporting beams are known, which consist of a number of C-shaped brick shells.

Here the brick shells are aligned with the opening upwards to form an elongated hollow space, in which a metal grid and possibly additional irons for reinforcement are introduced, and poured into the concrete.

Reinforced brick and concrete supporting beams are also known, which consist of a number of cross-section u-shaped, aligned brick shells, of which the inner elongated hollow space is filled with concrete, in which the reinforcing irons are sunk. These irons are introduced either prior to concrete pouring in oven starining using the technique used in the manufacture of prestressed products, or inserted after concrete pouring and moved axially until they are embedded into the concrete to the desired extent.

20 In both cases, a carrier strip, which meets the standards, is obtained, since the iron reinforcement is completely surrounded by the concrete, but it is not possible to manufacture supporting strips with a grid reinforcement in machine continuous production, '7> t

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----- -2- I. Noch since neither the brick shells with grate reinforcement inserted before concrete filling nor the brick shells with grate reinforcement inserted after concrete filling for the hardening of the concrete due to slipping of the reinforcement from the brick-5 shells when gripping the reinforcement can be transported. Transporting or relocating these building elements would only be possible with effective pallets or formworks placed underneath, which, however, is extremely time-consuming and expensive. The object of the invention is to provide a sling of the type mentioned in the preamble, which can be manufactured on an industrial scale without the use of pallets in continuous manufacture.

According to the invention, this object is achieved in that a groove is recessed in the opposite inner sides of the side walls of each brick shell in the bottom for receiving the unbent ends of brackets, which are provided with an upper longitudinal iron and with two lower longitudinal irons. form a grid reinforcement.

In order to make the use of spacers for the lower longitudinal irons of the lattice reinforcement superfluous and thereby save costs, in a design of the invention the lower longitudinal irons of the lattice reinforcement are welded to the brackets such that they pass through the side walls in the bottom of the brick shells themselves are kept an equal distance.

In a further embodiment of the invention, the bearing surface of 25 dg of groove for the stirrups is adapted to the course of the unbent end pieces of the stirrups, whereby the connection between the stirrups and the brick shell is increased.

In order to achieve an easy insertion of the end pieces of the stirrups into the grooves of the brick shells, in a preferred embodiment according to the invention the bottom of the brick shells is provided in cross section with a trough-shaped recess, which in the bottom surface of the opposite groove the side walls of the brick shells transitions.

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In a further preferred embodiment of the invention, each inner side of the side walls of the brick shells is provided above the groove for clamping the end pieces of the braces of the grid reinforcement with small ribs. This improves the bond between the concrete and the brick shells. i

In a further preferred embodiment of the invention, the braces of the grid reinforcement consist of separate elements welded to the longitudinal irons. In an alternative embodiment of the invention, the brackets of the grid reinforcement consist of a single continuous element, to which the longitudinal irons are welded.

According to a further embodiment of the invention, the metal reinforcement contains an extra iron, which is kept by the spacers lying in the brick shells at the required distance from the bottom of the brick shells. It is expedient here to secure the additional iron by snapping it into the plastic annular spacers.

The thoughts underlying the invention are explained in more detail in the following description with reference to a number of exemplary embodiments shown in the drawing.

20 Herein is:

Fig. 1 A crossbeam of brick and concrete according to the invention;

Fig. 2 A side view of the end portion of the carrier strip according to Figure 1 pp smaller scale and partly in section; Fig. 3 A view of a carrier strip according to Fig. 2 with another grating reinforcement and;

Fig. 4 A section through an alternative embodiment of a carrying strap according to the invention.

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The reinforced supporting beam of brick and concrete consists of a number of U-shaped brick shells 1 in cross-section. The aligned brick shells 1 delimit an elongated space, in which a grid reinforcement 2 and an added longitudinal iron 3 are inserted. Incidentally, the elongated space is filled with concrete 6. Each brick shell 1 has a continuous groove 5 in the opposite inner sides of the side walls 4 in the vicinity of the bottom 11. Furthermore, the side walls 4 of the brick shells 1 above the grooves 5 contain small ribs 12, which form the bond between the concrete 6 and improve the 10 brick shells 1.

The grid reinforcement 2 is composed of a number of brackets 7, to which two lower longitudinal irons 8 and an upper longitudinal iron 9 are welded. Separately, each stirrup 7, which in fact has the shape of an inverted V, has two top straight pieces 7a, which are mutually connected by means of a curved part 7b are connected, and two lower straight end pieces, which are bent connecting parts 7d are connected to the respective upper straight pieces 7a of the brackets.

The lower end pieces 7c are spread to a greater extent than the straight pieces 7a above. Inside the curved part 7b 20 between the two top pieces 7a, the top longitudinal iron 9 is welded firmly, while inside in each curved part 7d between each piece 7a and the respective end piece 7c a bottom longitudinal iron 8 is welded.

In view of the greater spread of the end pieces 7c in relation to the top pieces 7a, the longitudinal irons 8 outside 25 are consequently welded to the brackets 7.

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The grating reinforcement of which the brackets 7 consist of separate elements is used for the supporting belts shown in Figures 1 and 2. In contrast, Figure 3 shows a grid reinforcement 2 ', the brackets 7' of which consist of a single continuous element, to which the longitudinal irons 8 and 9 are welded. As can be seen in this case, the spread out bent ends of the continuous brackets 7 'lie in the grooves 5 of the brick shells 1.

The special shape of the grid reinforcement 2 allows the use of spacers 10 for the added irons 3, ensuring that it remains within the standards with regard to the smallest distance from the surface of the concrete. The additional iron 3 is secured by snapping into the plastic annular spacer 10.

In the embodiment of the carrier strip shown in figure 4 in the bottom 11 of the brick shells 1 provided in cross section with a trough-shaped recess 13, which transitions into the side walls 4 of the brick shells 1 in the bottom surface 14 of the opposite groove 5. Since the end pieces of the brackets 7 engaging in the grooves 5 are shorter than in the exemplary embodiment according to Figure 1, the two lower longitudinal irons 8 are welded to the brackets 7 inside. The distance from the longitudinal irons 8 to the trough-shaped recess 13 in the bottom 11 and to the side walls 4 of the brick shells 1 is thereby fixed variable. In order to increase the connection of the end pieces 7c of the brackets 7 to the brick shells 1, the bearing surface 5a of the grooves 5 for the brackets 7 is adapted to the course of the unbent end pieces 7c of the brackets 7.

To produce the carrier strip, the brick shells 120 are first aligned and in such a number as the desired total length of the carrier strip is required. In the elongated hollow space formed by the brick shells 1 aligned by the qp, the additional iron 3 is then inlaid when it is seen as required from the calculation of the supporting strip to be manufactured. This iron 3 is fixed by snapping into the spaced apart annular plastic spacers 10 which are present in the brick shells 1. The spacers 10 keep the additional iron 3 at the required distance from the bottom 11 of the brick shells 1. Then, in the elongated hollow space of the brick shells 1, the grating reinforcement 2, resp. 2 'fitted. With suitable devices, which are not the subject of the present invention, the grating reinforcement is compressed so far, until the transverse dimension allows the placement in the aligned brick shells 1. If the brackets 7, resp. 7 'the bottom 11, respectively. touch the trough-shaped recess 13 of the brick shells, the compressive action is reduced to such an extent that the elastic resilience. of the grating reinforcement causes the return to the original position, so that the spread end pieces 7c of the brackets 7 fit into the continuous grooves 5. Now the concrete 6 is poured into the long-pitched hollow space of the brick shells 1 for the complete filling thereof and subsequently, if necessary, before being shaken hard.

It is noted that, while in the known grating reinforcements, the brackets 7 resp. 7 'have the function, in order to keep the longitudinal irons 8 and 9 of 10 parallel to each other, in the case of the grid reinforcement used for the manufacture of the supporting strip according to the invention the brackets also have the function, the longitudinal irons 8 at a distance from the bottom and love the side walls of the brick shells 1. In this way, said longitudinal irons can be fully embedded in the concrete 15.

Due to the connection between the brick shells 1 and the grid reinforcement 2, 2, it is possible to move the supporting beam before it is hardened and also already poured before the concrete has been poured. This allows the manufacture of carrier bands on an industrial scale and consequently with an increased production speed and consequently lower costs.

Claims (9)

1. Reinforced brick and concrete carrier beam, which contains a number of brick shells in cross-section ü- or C-shaped, arranged in line to form an elongated hollow space, the hollow space receiving the concrete and the metal reinforcement. characterized in that a groove is recessed in the opposing interior of the side walls (4) of each brick shell (1) near the bottom (11) for receiving the unbent ends of brackets (7,7 '}, which an upper longitudinal iron (9) and with two lower longitudinal irons (8) form a lattice reinforcement (2,2 *). Reinforced carrier strip according to claim 1, characterized in that the lower longitudinal irons (8) of the grid reinforcement (2,2 ') are welded to the bracket (7,7'} so that they pass through the side walls (4) and the bottom (11) of the brick shells (1) themselves must be kept at the same distance. Reinforced truss according to claims 1 and 2, characterized in that the bearing surface (5a) of the groove (5) for the brackets (7,7 ') along the course of the unbent end pieces (7c) of the brackets (7 , 7 ') has been adjusted. Reinforced truss according to claims 1 to 3, characterized in that the bottom (11) of the brick shells (1) is provided in cross section with a trough-shaped recess (13), which is located in the bottom surface (14) of the opposite grooves (5) in the side walls (4) of the brick shells (1). 1 Reinforced carrier strip according to claims 1 to 4, characterized in that each inner side of the side walls (4) of the brick shells (1) above the groove (5) for receiving the end pieces (7c) of the brackets (7, 7 ') of the grid reinforcement (2,2') is provided with small ribs. -8- Reinforced supporting strip according to claims 1 to 5, characterized in that the brackets (7) of the grid reinforcement (2) consist of separate elements welded to the longitudinal bars (8/9). Reinforced supporting strip according to claims 1 to 5, characterized in that the brackets (7 ') of the grid reinforcement (2') consist of a single continuous element, to which the longitudinal irons (8,9) are welded. Reinforced truss according to Claims 1 to 7, characterized in that the metal reinforcement contains an additional iron (3), which is provided by spacers (10) lying in the brick shells (1) at the required distance from the bottom (11) of the brick shells (1) are held. Reinforced carrier strip according to claims 1 to 8, characterized in that the additional iron (3) is secured by snapping into the plastic annular spacers (10).