FI70289C - ARMERINGSNAET - Google Patents

Description

1 70289

The Welded steel mesh

The invention relates to a reinforcing steel mesh having longitudinal and transverse sections which are intersected with each other and which are preferably connected to each other at the intersection points 5.

There are certain difficulties associated with surface reinforcements formed from such reinforcing bars. Firstly, the concrete reinforcement must fit as well as possible into as many as 10 building elements of different dimensions, the width of which requires steels of different strengths. On the other hand, due to the economics of the production and storage of reinforcing bars, the number of different nets for sale (external dimensions, mesh size and steel strength) should be kept to a minimum.

The maximum width of reinforcing bars currently available is limited, mainly due to transport issues (eg 2.4 m in Austria and 2.15 m in Germany). As a result, certain building elements, e.g.

20 intermediate floors of apartment buildings, can only be reinforced by placing several nets next to each other, the length of which is sufficient to reinforce the elements in one direction, so that the entire surface of the elements can be reinforced. In order to be able to transfer the forces in the building element in the direction of the transverse wires (steels) of the nets, the edges of the adjacent nets must overlap in accordance with the relevant standards, i.e. a certain maximum value must be observed for the number of meshes and welding points. For example, in Austria and Germany, such a maximum value is the so-called in splice joints (Ver-teilerstösse) in the case of single-axis reinforced building elements, one mesh and again three meshes, the so-called in support joints (Tragstösse) in the case of biaxially reinforced tiles.

35 This poses another problem. If the longitudinal yarns of the netting are divided over a part of the entire width of the net so that their mutual distances are equal, several yarns come to the overlapping point. However, this inevitable loss of material has so far clearly had to be accepted.

However, in order to eliminate this drawback, specially constructed reinforced concrete nets have been developed, the so-called edge saving networks ("Randsparmatten"). These nets (U.S. Pat. No. 204,497, German Pat. No. 1,609,849) are made with longitudinal yarn openings at their edges in which the longitudinal yarns of an adjacent net are located when the nets overlap. In this case, the wire strength characteristic of a certain type of net is also obtained at the joints, the longitudinal wires also being distributed approximately 15 evenly over the entire reinforcement part. The advantage of such edge-saving nets is that their correct placement is easy to ascertain with the naked eye, since the distance between the yarns (mesh size) is then the same throughout. Po. however, nets are of no help when the 20th smallest possible selection of netting types is used to perform concrete reinforcement work that meets many different requirements.

On the other hand, it is known that when using the so-called. regular reinforcing steel meshes with the same longitudinal and transverse steel diameters and mutual distances, these can be overlapped at their edges with adjacent meshes so that the steels entering the overlapping points, if the meshes are not very wide, are distributed fairly evenly over the entire width of the reinforcing building element. Consequently, when these overlapping zones are widened, the steel cross-section entering the building element can be increased as required and almost steplessly compared to the steel strength of the separate meshes.

Using this method, it is in principle possible to adapt the steel cross-section of the reinforced building element to the current requirements in this respect with a relatively small selection of meshes, i.e. the reinforcing steel mesh reinforcement adapts very well to the different widths of the building elements. However, in order to achieve economically advantageous and technically reliable results using this method, it is necessary to first find out from the construction office which mesh types and edge overlap widths are used to obtain the best results- In addition, the reinforcement drawings must indicate the necessary overlap widths at the construction site. inspected when the work is completed.

The requirements for compliance with the given dimensions and inspection of the work performed are often not met, as it is almost impossible to detect the overlapping width of the net at the beginning and end of the net and the overlap width of two adjacent nets, especially in cross-reinforced tiles 15 with many intersecting and similar meshes.

The object of the present invention is to develop a reinforcing steel mesh in such a way that, when used, a number of different and easily visible edges of the mesh can be obtained, so that in the case of a certain range of meshes, regular nets and so-called compared to the reinforcement methods performed with edge saving nets 25, more options are obtained, however, the number of netting types remains smaller. In this case, it is of course also possible that, compared with the standard programs of regular reinforcing bars, both the strengths of the mesh steels 30 and the number of mesh types can be varied.

This is solved in a reinforcing steel mesh according to the invention, which has longitudinal and transverse sections which are intersected and preferably joined at each other at the intersections, so that a) it has inner longitudinal wires equidistant from each other, b) there are several inner longitudinal wires on each side. (C) the distance between the axes of these longitudinal sections is similar but greater than the distance between the axes of the inner longitudinal threads, and (d) at least one longitudinal section on each side of the net, preferably the innermost part, is clearly visible to the naked eye long-full parts over their entire length because it is different in shape or appearance.

Since the distance between the longitudinal wires (the width of the mesh 10) is now different in the middle part of the net and in the longitudinal parts at the edge of the net, by combining two longitudinal parts with a different structure from the middle part of the net, clearly different overlapping patterns can be obtained.

15 for splice joints, support joints and an even stronger overlap structure. The number of wires can then also be calculated in biaxial reinforcements and the location of the nets can be checked with the naked eye without measuring devices, as will be described later in connection with a structural example.

The distances between the longitudinal steels at the edges of the nets are preferably 1.5-2 times greater than in the middle of the net, so that the edge meshes can be clearly distinguished from their normal meshes and the maximum mesh size specified in the standards for individual loads is not exceeded.

In a preferred construction, most longitudinal sections at each side of the net always have two spaced apart parallel wires (steel) and at least one longitudinal section, preferably the innermost, closely spaced longitudinal wires (2 pieces) or one wire larger than the diameter of the net. other longitudinal threads. When two parallel wires 5 70289 at a certain distance from each other are used in the outer longitudinal parts, the edge parts can be anchored to the concrete very well / because the concrete can protrude between the two wires. Again, when two closely spaced longitudinal yarns or one thicker lan-5 is used for the inner longitudinal portion on each side of the net, the inner boundary meshes at the edges of the net become more clearly visible.

In other structures according to the invention, the longitudinal part is separated from the other longitudinal parts of the network by the so-called marking-10 with parts distributed over certain distances po. over the entire length of the longitudinal portion.

The cross-sections can be transverse parts arranged between two parallel longitudinal steels at a certain distance from each other, e.g. metal strips, or marking points (bent parts) placed at the intersection of the cross-sections and one longitudinal part at the edge. In addition, plastic sleeves of different colors arranged at a certain distance on the longitudinal parts at the edge can be used as marking parts.

20 When such markings are placed at regular but not excessive distances (e.g.

1 m) at a distance from each other, the longitudinal sections at the edge of the net shall be clearly visible in each section of the net, even when the net is cut into several sections.

25 In addition, the marking parts may be marked to indicate the type of network in question. Until now, reinforcing bars have generally been provided with labels / attached to one or both ends of the mesh. Such labels can easily tear when transporting the net and cutting the net into many parts on the construction site, as is very often the case, some parts are left without a type designation. The identification of such parts often has to be done by measuring the strength of the steel, which naturally takes its own time.

The invention will now be described in more detail by means of some preferred structural examples, with reference to the accompanying drawing, in which Fig. 1 shows a reinforcing steel mesh according to the invention with three wider meshes on each side, Fig. 2 is an enlarged cross-section of the left edge of Fig. 1 3, 4 and 5 show overlapping joints of two adjacent nets according to Figure 1, in which one longitudinal part or two or all three longitudinal parts 1Q are connected to the outer edge mesh of the other net or to both outer edge meshes or three edge meshes when two nets are placed side by side; Fig. 7 is an enlarged plan view of a marking portion 15 disposed on a pair of steel at the edge of the net, Fig. 8 is an enlarged cross-section of the steel pair of Fig. 7, Fig. 9 is a plan view of another structure according to the invention, Fig. 10 is an enlarged plan view of Fig. 11 is a plan view of a third net according to the invention, and Fig. 12 is an enlarged view of a marking portion of the longitudinal portions at the edges of the net.

In the central part of the net shown in Figures 1 and 2, longitudinal wires (steels) 1 are arranged at equal distances (a) from each other. In both edges of the net, at greater distances (ka) from each other and also from the outermost longitudinal wire 1 of the central part of the net, there are three longitudinal parts which are pairs of wires 2, 3 and 4. In this case all longitudinal wires are preferably connected to the transverse wires 5 by welding. The coefficient (k) is, as already mentioned, preferably 1.5-2. Thus, three edge meshes are obtained at each edge of the net 7 70289, which are clearly wider than the meshes in the middle part of the net.

The inner pair of yarns 2 of each edge comprises two yarns 2a and 2b contacting each other, while the outer pairs of yarns 3 and 4 of each edge comprise two yarns 3a, 3b and 4a, 4b, the distance (e) between which is so large that ao. both wires of the wire pair are covered with concrete and anchored to it. According to the standards in force in Austria, the distance (e) should be, for example, two 10 times the diameter of the steel in question, but at least 20 mm.

Figure 3 shows the edges of two adjacent nets which overlap so that the pair of yarns 4 of the other net enters the outer edge of the other net. In this case, a free edge mesh is clearly left between the pair of yarns 2 and the adjacent pair of yarns 3 15, and between the overlap joint and the middle part of the net there are two more free edge meshes from which this overlapping method can also be identified.

In the overlapping structure shown in Fig. 4, in which 20 pairs of yarns 3 and 4 of an adjacent net are placed in the outer edge meshes of each net, another free edge mesh remains between the pair of yarns 2 and the nearest longitudinal yarn 1 (belonging to the middle part of the net).

In the structure according to Fig. 5, pairs of yarns 2, 3 and 4 of an adjacent net are placed in all three edge meshes of the net 25.

As can be seen from Figures 3-5, the different structures shown therein (different steel thicknesses and mesh widths) can be clearly distinguished from each other.

In the network shown in Fig. 6, the main part of which is the longitudinal wires 1 and the transverse wires 5 welded to each other at the intersections, the longitudinal parts 2 of the edges are formed as pairs of wires (steel pairs). They consist of two closely related separate yarns. The longitudinal portions 3 and 4 at both edges of the mesh-35 are instead 70289 formed as pairs of yarns, always with two separate yarns at a certain distance from each other. The distance between the wires is then such that both wires sink well into the concrete. Each po. the distance between the wires of the pair of yarns lan-5 is then considerably smaller than the distance between the wires 1 in the middle part of the net and thus also considerably smaller than the distance between the longitudinal elements 2, 3 and 4 at the edges of the net, preferably 20-50 mm.

As can be seen from Figs. 7 and 8, metal strips 6 are welded transversely between two parallel wires of the longitudinal portion 4 of the edge, which, according to Fig. 7, may also bear the type designation of the net in question.

The central part of the net shown in Fig. 9 now has 15 separate longitudinal wires 1, whereas on each side of the net are arranged longitudinal parts 7 and 8 larger than the eyes of the central part of the net, welded to the longitudinal wires 5. The parts 7 and 8 each comprise two wires spaced apart. -2Q della apart. In order to be able to clearly separate these longitudinal parts when the nets overlap, the transverse yarns 5 are bent as shown in Fig. 10 at a point 9 of the pair of yarns 7, i.e. between the longitudinal yarns into a wave shape, while between the pair of yarns 8 the transverse yarns 5 are straight. The advantage of this marking structure is that it can be manufactured in conventional rebar welding machines with the help of simple accessories.

Fig. 11 shows a net structure according to the invention, which still consists of longitudinal yarns 1 in the central part, longitudinal parts 2, 3 and 4 at the edges and transverse yarns 5. In this construction example, the edge parts 2-4 formed of separate yarns are provided with regular patterned 35 marking parts lo, 10b and 10c, so that they can be separated from each other and from the middle part of the net.

70289

Figure 12 shows a marking substructure structure. These are plastic sleeves 10 of different colors, which are marked with the respective net type designation. As is the case in Austria, the letter to be marked (5 "A" in Figure 12) means nets with well-defined axial distances between the longitudinal and transverse sections, while the numbers ("38" in Figure 12) indicate the diameter of the longitudinal wires expressed as 1/10 mm. In order to distinguish them from each other, the marking parts 10 can be red in the edge part 1Q 4, yellow in the part 3 and green again in the longitudinal part 2. Such colored marking parts are also easy to notice in the overlapping of nets.

The structural examples described above can be modified within the scope of the invention in many different ways. For example, instead of three edge meshes, even more such wide edge meshes may be provided on each edge of the net. The edge portions and the longitudinal portions of the central portion can also be separated from each other in other ways. In this case, for example, stronger steel can be used and / or cantilever steels 1. can always be used for some longitudinal parts.

At the ends of the building elements to be reinforced, residual pieces can still be used to save material, which always occur on the construction site when the nets have to be cut, or smaller nets with a width of, for example, half the width of a normal net can be prepared separately. Such halves then have only wider eyes formed by longitudinal sections at one edge.

Claims (4)

70289 1. A reinforcing steel mesh with longitudinal (1-4, 7, 8) and transverse parts (5) intersecting and preferably connected to each other at the intersections by welding 5, characterized in that a) it has an equally long distance (a) from each other b) on both sides of these inner longitudinal wires 10 there are several longitudinal sections (2, 3, 4, 7, 8) different from the longitudinal wires of the inner network c) the distance (ka) of the axes of these longitudinal sections is similar to each other, but greater than that of the inner longitudinal wires (ka). the distance between the axes of the longitudinal yarns (a), and 15 d) at least one longitudinal part (2, 3, 4) at each side of the net, preferably the innermost part (2), clearly stands out to the naked eye from the other longitudinal parts (3, 4) along its entire length different in design or appearance. Net according to Claim 1, characterized in that the mutual distances (ka) of the longitudinal sections (2, 3, 4) at the edges of the net are 1.5 to 2 times greater than the mutual distances (ka) of the longitudinal wires (1) in the central part of the net. a). A net according to claim 1, characterized in that the majority of the longitudinal parts (3, 4) on each side of the mat each consist of two parallel wires (3a, 3b; 4a, 4b) spaced apart and that at least one longitudinal the whole part (2), preferably the innermost part, consists of closely related longitudinal yarns (2a, 2b) or one yarn larger in diameter than the yarns (3a, 3b; 4a, 4b) of the other longitudinal parts (3, 4) and the longitudinal yarns in the middle part of the net (1). Net according to Claim 1, characterized in that one longitudinal section (4; 7) is separated from the memory (2, 3; 8) by marking sections (6; 9; 10) which are distributed over certain distances along the entire length of the longitudinal section. Net according to Claim 4, characterized in that the marking parts are formed as transverse parts, in particular metal strips (6), arranged between two parallel wires (4) spaced apart from one another. Net according to Claim 4, characterized in that wave-shaped bends (9) arranged at the intersection of the longitudinal part (7) on the edge, e.g. in the transverse parts (5), are used as marking parts. Net according to Claim 4, characterized in that the marking parts are formed as plastic sleeves (10a, 10b, 10c) of different colors arranged in the longitudinal parts (2, 3, 4) at the edges at certain distances. Net according to one or more of Claims 4 to 7, characterized in that each marking part (6, 10) is preferably provided with a marking indicating the type of net. Paten tkrav: 702 8 9 1. Betonarmeringsnät bestäende av medandra korsande och i korsningspunkterna med varandra, företrä-5 desvis genome svetsning förbundna längs- (1-4, 7, 8) ocvelementement (5), kännetecknat därav, att a) det omfattarpä lika avst (b) the name of the second-hand line (1), (b) the number of cross-border lines (1, 3, 4, 7, 8), (c) the number of lines (1, 3, 4, 7, 8); in the case of an axle element, the axle of the axle (2), and in the case of an axle, (15) sig med blotta ögat klart frän de övriga längs-elementen (3, 4) utmed hela sin längd, emedan detta account sin utformning eller account sitt utseende är olika. 20 2. A patent according to claim 1, which is defined as having a further element (2, 3, 4) and an angle of 1.5 to 2 parts pertaining to the first element (a) of the first element (a). 1) i nätets mittparti. 25 3. A patent according to claim 1, which is further adapted to comprise a latch element (3, 4) and a matrix of the right edge of the head or to a plurality of a plurality of parallel plates (3a, 3b; 4a, 4b). oct attestant to the sloping element (2), 30 means having an inner slope (2a, 2b) or a diameter of the sloping element (2a, 2b) or a diameter of the sloping element (3, 4); 3a, 3b, 4a, 4b) and a longitudinal arm (1) are not shown. 35 4. A patent according to claim 1, having a transverse view, comprising a sliding element (4; 7)