KR100222282B1 - A latticed mat of steel bar for the reinforcing concrete - Google Patents

Abstract

The present invention relates to a reinforced grid mat for reinforced concrete consisting of longitudinal and transverse wires welded to each other at grid intersections. In particular, the transverse end portions 7 which are bent in a ring shape in the direction towards the edge longitudinal wires 2, 3 in a lattice plane projecting past the edge longitudinal wires 2, 3 are at least the edge longitudinal wires. The two longitudinal longitudinal wires (2, 3) at each mat edge have a smaller cross-sectional area (f) than the longitudinal wire (1) in the mat internal zone, welded with one (3) of the mat internal zone. The inner longitudinal wires 1 have the same spacing a and the same cross-sectional area F, and all the longitudinal longitudinal wires 2 relating to the cross-sectional area F of all longitudinal wires 1 and the overall mat width in the mat interior region. Reinforced lattice mat for reinforced concrete, where the sum of the cross sectional areas (f) of (3) is equal to the cross sectional area (F) of the longitudinal wires (1) in the mat inner region in relation to the mutual axle distance (a) of the longitudinal wires (1). It is about.

Description

Reinforcing grid mats for reinforced concrete

1 is a plan view of a reinforced grid mat according to the present invention.

2 is a plan view of the edges of the reinforced grid mat shown in FIG.

3 is a plan view of a modified reinforced grid mat.

4 is a plan view of the corners of the reinforced grid mat according to FIG.

* Explanation of symbols for main parts of the drawings

1: Longitudinal wire 2,3: Longitudinal longitudinal wire

4: transverse wire 5: unit grid

8: ring

The present invention relates to a reinforced grid mat for reinforced concrete consisting of longitudinal and transverse wires welded to each other at grid intersections.

In the reinforcing lattice mat of this kind known from the Federal Republic of Germany Patent No. 23 15 520, all the longitudinal members are formed in the form of wire pairs by reinforcing fillets in which at least several longitudinal members are welded at equal intervals. The longitudinal wire ends are bent in a ring shape with respect to the edge longitudinal members for the edge side reinforcement of the mat, which allows the formation of a secure mat seam.

In another such type of reinforced lattice mat known from Federal Republic of Germany Patent No. 23 50 866, the longitudinal members are also equally spaced apart, and two parallel adjacent transverse wires are connected to each other. And their ends protruding past the edge longitudinal members are bent in a ring shape such that both transverse wires are welded with the longitudinal members together with the loop to be almost closed and have two parallel longitudinal sides and a narrow side bent in a semicircular shape. A wire ring is formed.

The seams of the known lattice mats can be formed by pushing the two lattice mats until their edge longitudinal wires are located next to each other and the rings of the lattice mats overlap. In this case, in the known grid mats, in order to improve the force transmission at each mat edge, the annular longitudinal wire end portions are extended beyond the two outer edge longitudinal members and optionally other longitudinal members so that they Can be welded with. The same effect can be obtained by lengthening the ring length protruding past the mat edge. However, the improvement in force transmission achieved in these cases would significantly increase the cost of the transwire material. Another drawback with these methods is that, when adhering to the lattice width of the standard mat width, grating sheets with transverse lengths of large protrusion lengths required for the ring shape cannot be manufactured in lattice welding machines fitted to the standard lattice. .

Improvements in the transverse force transfer can also be achieved by overlapping the mat by at least one unit grid section in known grid mats. However, this has the disadvantage that twice as many wire materials are used as are necessary to absorb the force in the overlapping range.

Rebar grid mats are relatively long in length, but are manufactured only in limited widths in view of their handling and transport by truck and railroad, so in practice they have a wide variety of support structures for reinforcement structures consisting of multiple side-by-side grid mats. In order to match the dimensions, the reinforcing bars must be assembled together in the longitudinal wire direction of the lattice mat, thereby increasing the above-mentioned material loss in the overlapping range.

It is an object of the present invention to provide a reinforcing steel reinforcing bar assembled by these lattice mats so as to achieve optimal force transmission between the transverse wires of adjacent lattice mats in the above-described reinforcing lattice mats. At the minimum material cost of the longitudinal wires, the reinforcement grid mats are formed to meet the wide limits of the dimensions of the various supporting structures in the cross-wire direction, and at the same time the level of the cross-sectional area of successive mat thicknesses is as small as possible. Reinforcing bars are formed so that all reinforcing problems for the shaped reinforced concrete structures can be solved.

Reinforcing lattice mats of the kind mentioned at the outset are, in accordance with the present invention, transverse wire end portions that are bent in a ring shape in the direction towards the soft longitudinal wires within the grating plane projecting past the soft longitudinal wires, at least both of the soft edges. Welded with one of the wires, the two longitudinal longitudinal wires at each mat edge have a smaller cross sectional area than the longitudinal wires in the mat internal zone, wherein the longitudinal wires in the internal mat zone have the same mutual spacing and same cross section. It has an area, and the following relation

(Where B is the mat width and N is the number of longitudinal wires in the mat interior region).

According to a preferred embodiment of the present invention, the ratio of the cross sectional area of the soft longitudinal wire to the cross sectional area of the longitudinal wire in the area inside the mat

And thereby the ratio of the diameter of the soft longitudinal wire to the diameter of the longitudinal wire in the area inside the mat.

Where the preferred mat width is 2400 to be.

Also subject to the present invention is a set of reinforced grid mats having an increased wire cross-sectional area, wherein the diameter of the longitudinal wire in the mat interior region of one reinforced grid mat is equal to the diameter of the soft longitudinal wire of the nearest adjacent reinforced grid mat of the set. It is characterized by the same.

Further features and advantages of the present invention will be described in detail with reference to the accompanying drawings in two embodiments.

In Figures 1 and 2, it can be seen that there is a longitudinal wire 1 in the inner region of the reinforcing lattice mat and an inner edge longitudinal wire 2 and an outer edge longitudinal wire 3 at the false mat edge. The longitudinal wires 1 in the area inside the mat are arranged at mutually spaced intervals a so-called longitudinal wire distributions, which are measured from the wire center to the wire center, respectively. The two edge longitudinal wires 2, 3 are arranged at a spacing b much narrower than the spacing a of the longitudinal wires 1 in the mat interior region. The interval b is 20 to 50 Is preferred. Since the spacing (b) of the two edge longitudinal wires (2,3) is narrow, when multiple reinforced grid mats are used to reinforce the reinforced concrete structure, the transverse wires of two adjacent reinforced grid mats are thus followed (4) Since the overlapping distance in the joint is shortened, the transverse wire material is saved.

The inner edge longitudinal wires 2 are preferably arranged at an interval c larger than the spacing a of the longitudinal wires 1 in the mat internal region, respectively, from adjacent longitudinal wires 1. According to this preferred configuration of the reinforcing bar mats, when a plurality of reinforcing lattice mats are connected side by side and superimposed laterally on each other, their overlapping edges form support joints, so that the rebar cross-section is almost over the entire reinforcement surface. It is evenly distributed. The material is saved by preventing undesirable reinforcement overlap on the overlap. However, the spacing c may be selected to be equal to the spacing a of the longitudinal wires 1 in the mat inner region.

The transverse wires 4 extend at right angles to the longitudinal wires 1 and the edge longitudinal wires 2, 3 and are welded to the longitudinal wires 1 and the longitudinal longitudinal wires 2, 3 at each grid intersection. These transverse wires 4 are arranged at mutually spaced intervals e having the same transverse wire distribution, respectively, which is the spacing a of the longitudinal wires 1 in the mat inner region in the embodiment according to FIGS. 1 and 2. Wider

Further, in this embodiment, the longitudinal and transverse wires in the inner region of the reinforcing lattice mat also form the unit grid 5 having a rectangular shape. The end portions 7 of the transverse wires 4 protruding beyond the outer edge longitudinal wires 3 are bent in a ring 8 symmetrically with respect to the longitudinal wires 1 of the reinforcing lattice mat at each mat edge and at the intersection In (9), it is welded with the said external edge longitudinal wire (3). However, the rings 8 may be bent in opposite directions with respect to each other at each mat edge. It is also possible to guide the ring 8 to the inner edge longitudinal wire 2 and weld it only to the inner edge longitudinal wire 2 or to both edge longitudinal wires 2, 3. The inner diameter of the ring 8 is selected so that the allowable concrete pressure in the bending area of the ring is not excessive when installed in the reinforced concrete. The diameter is preferably four to six times the diameter h of the transverse wire 4.

The distance (g) from the center of the outer edge longitudinal wire (3) to the outer ring edge is 50 It is preferable to select as. By means of the arrangement of the rings 8, together with the dense arrangement of the edge longitudinal wires 2, 3, within the overlapping seam of the two reinforcing lattice mats, the part of each transverse wire placed in front of the ring and the two outer ones The two weld points between the edge longitudinal wires 2, 3 contribute to a nearly uniform force transfer due to their narrow spacing b, thereby reducing the load on each weld point. Additionally, the hooks 8 at the mat edges provide good fixation of the reinforced grid mats that overlap each other in the overlap seams. Since the hooks 8 at the mat edges make it possible to clearly know the position of their edges when joining multiple reinforced grid mats, it is possible to precisely form the actual overlapping position so that the laying arrangement of the reinforced grid mats at the construction site is always easy. You can.

The sum of all the gaps a, b, c and the ring projection distance g is the mat width B, which is freely selectable. In general, the mat width B is chosen as standard size as small as possible depending on the vehicle loading width of the reinforced grid mat. For example, in Austria the mat width (B) is 2400 to be.

In the second embodiment of the reinforced grid mat shown in FIGS. 3 and 4, the spacing e of the transverse wires 4 is equal to the spacing a of the longitudinal wires 1 in the mat inner region, Different from the first embodiment in that the longitudinal and transverse wires form a square unit cell 5.

These reinforced grid mats can be produced in any length.

The diameter d of the edge longitudinal wires 2, 3 is selected to be smaller than the diameter D of the longitudinal wires 1 in the mat internal region within the scope of the present invention. By this measure, it is possible to prevent the reinforcement of rebar at the overlapping position of two rebar lattice mats.

If the cross sectional area of the longitudinal wires 1 in the area inside the mat is denoted by F, the cross sectional area of the longitudinal longitudinal wires 2, 3 is denoted by f and the number of longitudinal wires 1 in the internal area of the mat is denoted by N,

When satisfying, the cross-sectional area of the reinforcement laid for the reinforcing bar mats according to the present invention will be distributed substantially uniformly over the entire reinforcing bar lattice, ie the cross-sectional area and the total of all longitudinal wires 1 in the area inside the mat. The ratio of the sum of all edge longitudinal wires (2,3) cross-sectional area to mat width (B) should be equal to the ratio of the cross-sectional area of longitudinal wires (1) in the mat interior region to the spacing (a) of the longitudinal wires (1). do.

2400 For the general mat width of, the condition is that the ratio of the two cross sectional areas F and f is independent of the spacing a of the longitudinal wires 1 of the area inside the mat.

To be The relation between the diameters D and d of the longitudinal wires thereby

Is obtained.

Based on the relationship according to the present invention between the cross-sectional area of the longitudinal wire and the cross-sectional area of the soft longitudinal wire, a series of reinforced grid mats having an increased cross-sectional area can be used to solve all reinforcement objectives for flat laid reinforced concrete structures. Can be used. The first possible diameter d of the longitudinal longitudinal wires 2, 3 closest to the diameter D of the longitudinal wires 1 in the area inside the mat is then determined first. Completed set of reinforcing bars in which the diameter (D) of the longitudinal wire (1) in the area inside the mat coincides with the diameter (d ') of the soft longitudinal wire (2, 3) of the closest upper reinforcing lattice mat. When the lattice mat was made, it was proved that all the reinforcing objectives actually produced could be achieved. The smallest possible diameter d, which is preselected as possible, is presented by a thinner wire due to specification determination and limited workability.

Further, within the scope of the present invention, starting from the desired maximum possible diameter D of the longitudinal wire 1 in the mat inner region, conversely, the performance longitudinal wires 2,3 based on the relational expression according to the present invention. It is also possible to calculate the corresponding diameter d of) and then find the nearest reinforcement lattice mat of the set.

Based on the above relationship, a cross-sectional area difference of about 25% will appear between a set of individual grating mats.

For manufacturing reasons, the value of diameter D or d can be advantageously raised or lowered to an integer value without departing from the spirit of the invention.

If there are not enough microsteps between the reinforcing grid mats to address all reinforcement objectives, a set of mats can be made with even finer steps where the cross-sectional area gap is half the value previously suggested. In this case the ratio between diameters D and d

Becomes

Within the scope of the present invention, it is also possible to provide a transverse wire 4 having a diameter h equal to the diameter D of the longitudinal wire 1 of the mat inner region. In this case, the bearing force of the reinforcing lattice mat in the lateral wire direction is the same as the bearing force in the longitudinal wire direction. However, it is also possible to match the diameter h of the transverse wire 4 with the diameter d of the edge longitudinal wires 2, 3. In this case, the supporting force of the reinforcing lattice mat in the transverse direction is determined by the selection of the transverse wire distribution e, and the supporting force of the reinforcing lattice mat in the longitudinal wire direction depends on the selection of the transverse wire distribution e. It's just a percentage of our support.

The longitudinal wires 1, the edge wires 2 and 3, and the transverse wires 4 may be provided with ribs or engravings on their outer surfaces, or may be formed so as to facilitate bonding of the wires in concrete.

Increased rebar cross section, 1 each Of the transverse wire 4 equal to the diameter D of the longitudinal wire 1 in the mat inner region, the unit grid 6 in the forward direction, and the diameter d of the longitudinal wire 1 in the mat inner region. A set of reinforcing lattice mats according to the invention having a diameter (h) and a mat width of 2 or 4 m, respectively, is for example as shown in the following table where the cross sections (F and f) per unit length (LE) are shown: Can be configured.

A set consisting of a rectangular lattice 5 and a reinforcing lattice mat according to the invention having a diameter h of transverse wires 4 equal to the diameter d of the edge longitudinal wires 2, 3 is for example It can be configured as follows.

Claims (8)

A reinforced grid mat for reinforced concrete having longitudinal and transverse wires welded to each other at grid intersections, the end portions of the transverse wires being bent in a ring, in a plane projecting past the edge wires (2,3). Transverse wire end portions 7 which are bent in a ring shape in the direction towards the edge longitudinal wires 2, 3 are welded with at least one of the playing longitudinal wires 3 and both edge edges at each mat edge The wires 2, 3 have a smaller cross sectional area f than the longitudinal wire 1 in the mat internal region, the longitudinal wires 1 in the mat having the same mutual spacing a and the same cross sectional area F. ) And the following relation, (Where B is the mat width and N is the number of longitudinal wires in the area inside the mat) Reinforcing grid mat for reinforced concrete, characterized in that to satisfy the. The ratio of the cross sectional area (f) of the edge longitudinal wires (2,3) to the cross sectional area (F) of the longitudinal wires (1) in the area inside the mat. And the ratio of the diameter d of the edge longitudinal wires 2,3 to the diameter D of the longitudinal wires 1 in the area inside the mat. The preferred mat width (B) is 2400 Reinforcing lattice mat for reinforced concrete characterized in that it is. 3. The two edge longitudinal wires (2, 3) at each of the mat edges, as is known per se, have a mutual spacing (a) between the longitudinal wires (1) in the mat interior region. Reinforcing grid mat for reinforced concrete, characterized in that arranged at a narrower interval (b) than. The distance c between the inner longitudinal longitudinal wire 2 and the longitudinal wire 1 of the mat interior region adjacent thereto is, as is known per se, the species in the mat interior region. A reinforced grid mat for reinforced concrete, characterized in that it is larger than the spacing (a) of the wire (1). The reinforced grid mat for reinforced concrete according to claim 1 or 2, wherein a diameter (h) of said transverse wires (4) is the same as a diameter (d) of said edge longitudinal wires (2,3). The reinforced grid mat for reinforced concrete according to claim 1 or 2, characterized in that the diameter (h) of the transverse wire (4) is the same as the diameter (D) of the longitudinal wire (1) in the mat inner region. The ratio of the diameter (d) of the edge longitudinal wires (2,3) to the diameter (D) of the longitudinal wires (1) in the mat inner region. And the preferred mat width (B) is 2400 Reinforced grid mat for reinforced concrete characterized in that it is. In a set of reinforcing lattice mats according to any one of claims 1 to 7, which has an increased wire cross-sectional area, the diameter (D) of the longitudinal wires (1) in one area of the reinforcing lattice mat is determined by A set of reinforced grid mats for reinforced concrete, characterized in that it is equal to the diameter (d ') of the longitudinal longitudinal wires (2,3) of the reinforced grid mats to be joined.