NO127117B - - Google Patents

Description

Reinforcement device for flat-like building parts made of concrete.

The invention relates to a reinforcement device for flat-like building parts made of concrete, consisting of reinforcement mats which are laid out with overlap and consist of longitudinal and transverse rods, which cross each other at right angles and are connected, preferably welded together at the crossing points.

Flat-like construction parts made of concrete, such as e.g. roof slabs, can be reinforced with individually laid steel rods or with reinforcement mats. When reinforcing with bars, it is possible to achieve the required statically calculated steel cross-sections with optional accuracy. To achieve a specific steel cross-section, it is sufficient to reduce respectively yoke . the mutual distances between the rods. If a reduction or increase of the distances is not appropriate or possible, poles with different diameters can be arranged. Thus, any building part can be reinforced statically and structurally correctly.' Reinforcement with rods is, however, labor-intensive, as each individual rod must be prepared and arranged separately.

The other reinforcement option for flat-like building parts made of concrete consists of 'using reinforcement mats'. Such mats comprise two rows of rods that cross each other - at right angles - length rods and distribution rods - which are usually joined by spot welding at the crossing points. For reasons related to the production and transport of these mats, they cannot be produced in optional dimensions. To reinforce a building part, they must therefore be laid out next to each other and with mutual overlap, which is necessary for further conduction of the rod forces.

The advantage of this type of reinforcement is that reinforcement units with large surface dimensions can be manufactured economically and accurately. As the individual work operations that are necessary for reinforcement with single bars, such as boyning, precise laying out and connection, will be omitted with finished reinforcement mats, these can be laid out quickly and safely. The rigid connection between longitudinal and transverse rods in the welding points also creates a good connection between reinforcement and concrete.

Admittedly, associated with the aforementioned advantages is a certain rigidity

in the design of such reinforcement mats. The steel cross-section for the longitudinal and transverse bars per width unit must be determined in advance for the production, and this applies to both the distances between the individual steel rods and the rod cross-sections used. In connection with the rod diameters offered by the industry, over the years a standardization has arisen with a view to the distances, so that only distances of 5o mm and a multiple thereof, as well as 75 mm and a multiple thereof, are used. The choice of distances is further limited by the fact that the mutual distance between supporting rods must not exceed 2oo mm, while the mutual distance between distributing rods must not exceed 333 mm"

Under these conditions, e.g. a cross-sectional area of 0.84 to 7>54 cm is provided by l8 different mat types. To enlarge the cross-sectional area, double rods have also been used, which consist of two rods arranged closely next to each other. The cross-sectional area was thereby increased to 15>o8 cm and the cross-sectional number, respectively the type number, to 2 x 18 = 36.

The variety of mat types and the large number of rod diameters that are necessary for the production of all these mat types strongly influence the production costs for reinforcing mats. In addition, the large number of types forms an obstacle to the desired automation in production. In addition, the share of the total costs for storage and storage is significant.

Despite this, even the said number of 36 different mat types is in many cases insufficient for a practical task of economic reinforcement. One therefore often uses two layers of reinforcing mats on top of each other to double the available steel cross-sections and the type number and by combining different types achieve additional cross-sections, thereby reducing the differences between two successive cross-sections at any time. With this measure, however, the costs for laying out the mats increase significantly.

In order to remedy the disadvantage that the steel cross-section (for example in reinforced concrete slabs with a parabolic moment distribution) is necessary in the middle of the field for the maximum bending moment, must be carried out in full size right up to the slab edges, where this cross-section size in and of itself is not necessary, so-called graded reinforcement has been used. This means that at all times the second layer of reinforcing mats is shortened in unison with the moment progression. With this measure, however, the number of different mat types and sizes increases further, so that the supply of work and the need for mats on the construction site increases.

A further problem with reinforcement with reinforcement mats lies in the fact that these must be laid out overlapping to secure the power transmission. If the individual reinforcing mats have longitudinal bars with the same steel cross-section up to the edges, the longitudinal bars will necessarily be double up in the overlapping areas. This entails a certain excess of steel, which cannot be calculated evenly distributed over the entire reinforcement area due to the large distances between the overlaps, which correspond to the mat width used at any given time.

Various proposals are known to avoid the additional steel cross-section in the overlap areas. A known proposal is that in the edge areas, in the overlap width, only longitudinal rods are arranged with a cross-section that corresponds to half of the other cross-sections of the rods. In this way, a cross-section corresponding to the normal cross-section of the bars is achieved, as two longitudinal bars with half the normal cross-section are laid on top of each other in the overlap area, which results in uniform reinforcement intensity over the entire reinforcement width. ...The invention is based on the task of providing an opportunity to combine the advantages of reinforcement with prefabricated mats and the advantages of the manifold variable reinforcement with single bars, while avoiding the disadvantages of the two forms of reinforcement. According to the invention, this task is solved by a 'type-correct' reinforcement device in that, in addition to the reinforcement mats that form a closed base reinforcement, narrow mat strips are arranged, which comprise at least two longitudinal bars that are connected by cross wires, at such a distance from each other that the local cross-sectional yokes thus created can be calculated evenly distributed over the entire reinforcement width and added to the steel cross-section of the base reinforcement.

In the new reinforcement arrangement, the base reinforcement can consist of reinforcement mats that have a constant steel cross-section over the entire width of the mat and the cross-section of the mat strips can approximately correspond to the cross-section existing in the overlap area between two base mats. However, the basic reinforcement can also consist of reinforcing mats, which in the laid out reinforcement form a constant cross-section over the entire width of the reinforcement and two mat strips can be arranged between two mat overlaps, the distance between the longitudinal center lines of the outermost strips at all times and the longitudinal center lines of the mat overlaps being half as large as the mutual distance between the strips.

In order for the distribution reinforcement to also be drawn into this system, it is appropriate that the narrow mat strips are arranged crossing in both bearing directions of the building part to be reinforced.

In this connection, it is considered sufficient that the length rods for the narrow mat strips are only connected by cross wires which secure the position of the length rods.

The narrow mat strips can also be arranged shortened in accordance with the bending moments and/or be boyed up towards the upper side of the building part being reinforced.

The advantage of the reinforcement device according to the invention is primarily that the reinforcement mats laid in the bottom (first)

layer, only includes the cross-sectional part which forms the base reinforcement and which for the reinforcement of a building part must run continuously from facility to facility, while the necessary cross-section is achieved with the upper (second) layer of narrow mat strips. With the arrangement of the second mat layer of narrow mat strips, depending on their number and mutual distance, a multiple of reinforcement cross-section can be achieved up to twice the value of the cross-section for the first layer of a base mat type.

By splitting the reinforcement cross-section into a basic reinforcement and an additional reinforcement of narrow mat strips, the combination possibilities are not only expanded and the number of mat types that must be kept in stock is reduced, but the production and stocking of the mats is simplified. Thus, one can with a small number of mat types of convention panel. type and i', the same height, a small number of strip types cover a cross-sectional area of approx. l,o to 45>° cm /m.

The special advantages of the new reinforcement device appear from the following considerations: If, for example, in the case of known reinforcement mats, 24 different mat types are required for a cross-sectional area of 0.92 to 22.62 cm to reinforce building parts with reinforcement extending in an axis, these 24 mat types will have 24 different cross-sections. As the necessary steel cross-sections, however, rarely correspond to the set cross-section series and under-reinforcement cannot be permitted for reasons of the structure's stability, over-reinforcement cannot be avoided. The extra consumption due to over-arting varies with the known mat systems between 0 and 2o%.

According to the invention, only 6 mats of the usual type and 5 types of mat strips are required to achieve the same cross-sectional area. With these 6 mat and 5 strip types, which e.g. distributed over the entire reinforcement width at distances of 1.0, 0.90, 0.80, 0.70, 0.60 and 0.50, 6 x 6 x 5 = 180 different cross-sections can be obtained. While a conventional mat program requires 18 different bar diameters, the reinforcement according to the invention necessarily only has 6 different bar diameters, as the base reinforcement's mat types can consist of the same bars as the strip types for the additional reinforcement.

A further advantage of the combination of a closed base reinforcement of the conventional type with an additional reinforcement in the form of narrow mat strips lies in the fact that additional strips, in the same way as was hitherto common with mat reinforcements, can end up in the area of tensile stresses, so that they can be arranged shortened corresponding to the bowing moments' foriop, just as they can be bowed up like this. it has so far only been possible with single rod reinforcements. Thereby, the graded reinforcement with reinforcing mats will also be applicable in all the areas where this has not been possible until now due to the expected shear stresses that could not be accommodated with reinforcing mats. The reinforcement parts that are not used in the tensile suspension area can be anchored by upward bending in the compression-tension area and thus used to take up the negative bending moments in the support area when slabs pass through several fields.

Another problem is that there must be different shares

of distribution reinforcements depending on whether a building part is to be reinforced in one or two axes. -Minimum5 of distribution reinforcement- constitutes 26 * fo of the -steel cross-section in the load-bearing reinforcement for plates that are stressed in one axis. So that it* can also be created intermediate values up to two-axle tension

plates with loo $ distribution reinforcement, different mat types are produced', 'where approx. 4°> 60 dg loo % of the current steel cross-section of the longitudinal bars is arranged as distribution reinforcement. Thus, the variety of mat types that must be kept in stock will be further increased.

With the reinforcing device according to the invention, optional steel cross-sections can be achieved with the aforementioned 6 different mat types and the 5 different strip types not only in one direction, but in two directions running perpendicular to each other.

Further features and advantages of the invention will be apparent from the embodiment examples which are shown in the drawing and discussed in more detail below. Fig. 1 shows a partial cross-section through a reinforcement using reinforcement mats with a constant steel cross-section. Fig. 2 shows a similar cross-section of a device with reinforcement mats to achieve uniform reinforcement intensity over the entire width of the reinforcement. Fig. 3 a to f shows a cross-section through the narrow mat strips which are designed according to the invention. Fig. 4 and 5 show cross-sections through construction parts which are reinforced with a reinforcement device according to the invention. Fig. 6 and 7 show schematically different arrangement options for the narrow mat strips in relation to the base reinforcement. Fig. 1 and 2 shall exclusively illuminate the background of the invention.

In fig. 1 shows a partial cross-section through a known reinforcing device. The reinforcing mats 1 consist of transverse bars 2 and longitudinal bars 3* The latter have a constant diameter over the entire width of the mat and are arranged at the same distance from each other. In the splice areas, two adjacent mats are overlapped at all times with a mesh, so that here you have two of the length bars 3", which implies an accumulation of steel cross-sections.

In the case of the likewise known reinforcing device which is shown in partial cross-section in fig. 2, in the 4 edge areas of the mats, longitudinal rods 5> are arranged in overlapping width, which have approx. half as large cross-section as the longitudinal bars 6 in the other mats. In this way, uniform reinforcement intensity is achieved, even in the overlaps.

Fig. 3 shows different embodiments of the mat strips according to the invention. The strip 7 in fig. 3a consists of two longitudinal rods 8, which are arranged at a mutual distance b. The longitudinal rods 8 are interconnected by means of cross wires 9. These connections can be made by welding, by means of metal or plastic clamps, by joining or gluing with plastic. The connection can be shear-resistant, so that the cross wires are also effective for anchoring in the concrete, or not shear-resistant, if the cross wires are only to be used to secure the position of the longitudinal bars 8 in relation to each other.

As shown in fig. 3 D °S c, one or both longitudinal rods 8 can be designed as double rods. There may also be three, four or five longitudinal bars 8 on the same width of the mat strip. The distance between the outermost longitudinal bars 8 is at least 2oo mm (fig. 3 d-f).

In fig. 4 and 5 show examples of the application of the invention to the reinforcement of a concrete slab. In fig. 4 are the mats 1, as shown in fig. 1, combined with each mat strip 7> which is arranged in the middle between two mat joints. When the steel cross-section of the mat strips 7 corresponds to that which occurs in the overlapping area, an average cross-section can be formed from these accumulations which can be calculated as an addition to that of the mats. 1 base cross-section, if it is distributed over the entire width of the reinforcement.

In example 5, the invention is shown used in connection with the example shown in fig. 2, which provides uniform reinforcement intensity over the entire width of the reinforcement. In addition to the basic reinforcement consisting of mats 4>, two mat strips 7 are arranged here at a distance from the joint areas that is approximately half the mutual distance of the mat strips. Thus, the cross-sectional accumulations are also here arranged at an even distance from each other, so that the calculated distribution of the additional cross-section in the form of steel accumulations over the entire reinforcement width is straight-finished.

In fig. 6 and 7 show further examples of how the mat strips can be arranged in relation to the splice distances that follow from the width of the reinforcing mats. Fig. 6 a shows the basic reinforcement of the mats 11. The distance between joint centers is denoted by S. If, in addition to this basic reinforcement, a mat strip 12 is laid out, this is conveniently arranged in the middle of each mat 11 (fig. 6b). In fig. 6c has two extra strips at a distance of 1/3 S both from each other and from the joint. The distances change with the increasing number of mat strips to l/4 S and l/5 S respectively (fig. 6d and e).

Fig. 7 shows examples where no accumulation of steel occurs in the joint areas between mats. The mats of the base reinforcement are denoted here by 13. In addition to the base reinforcement, in fig. 7b arranged two mat strips 12, which have a distance from the joint area that is half of the mutual distance between the strips 12. With regard to the entire reinforcement width, the cross-sectional accumulations which here alone are caused by the strips will thus be at an even distance from each other. This device can also be varied with three or further mat strips.

Claims (7)

1. Reinforcement device for flat-like building parts made of concrete, consisting of overlapping arranged reinforcement mats with longitudinal and transverse bars that cross each other at right angles and are connected, preferably, welded together at the crossing points, characterized in that in addition to the reinforcement mats that form a closed base reinforcement> is arranged narrow mat strips which at least comprise two longitudinal bars which are connected by means of cross bars, the strips being arranged at such a distance from each other that the resulting local cross-sectional accumulations can be calculated evenly distributed over the entire width of the reinforcement and added to the steel cross-section of the base reinforcement. 2. Reinforcement device as stated in claim 1, characterized in that the base reinforcement consists of reinforcement mats, which have a uniform steel cross-section over the entire width of the mat and that the cross-section of the mat strips corresponds approximately to that present in the overlapping area of two base reinforcement mats forming a joint. 3. Reinforcement device as stated in claim 1, characterized in that the base reinforcement consists of reinforcement mats which in the laid reinforcement formed a constant steel cross-section over the entire width of the reinforcement and that at least two mat strips are arranged between two mat joints, so that the distance between the longitudinal center lines for the outer strips at all times from the longitudinal center lines for the mat joints are half of the mutual distance between the strips. 4. Reinforcement device as stated in one of the claims 1-3" characterized in that the narrow mat strips are arranged crossing in both bearing directions of the building part being reinforced. 5. Reinforcement device as set forth in one of claims 1-4, characterized in that the length rods for the narrow mat strips are exclusively interconnected by cross wires which secure the length rods against displacement. 6. Reinforcement device as specified in one of the claims 1-5> characterized in that the mat strips are shortened in accordance with the course of the bending moments. 7. Reinforcement device as specified in one of claims 1-6, characterized in that the narrow mat strips are built up against the upper side of the building part being reinforced.