EP4225517A1

EP4225517A1 - Machine and method for producing simply reinforced steel wire meshes

Info

Publication number: EP4225517A1
Application number: EP21763389.0A
Authority: EP
Inventors: Franz HÄUSSLER; Alexander STUFLESSER
Original assignee: BAM AG; Progress Maschinen and Automation AG
Current assignee: BAM AG; Progress Maschinen and Automation AG
Priority date: 2020-10-09
Filing date: 2021-08-30
Publication date: 2023-08-16
Also published as: WO2022073695A1; AU2021358290B2; JP2023545805A; AU2021358290A1; DE102020126584B3; US20230330737A1; CA3189863A1

Abstract

The present invention relates to a machine and a method for producing simply reinforced steel wire meshes, in particular for uses with not predominantly static loading, reinforcement wires being fastened to supporting strips by means of individual wire tying.

Description

Machine and method for manufacturing uniaxial reinforcing steel bars

The present invention relates to one, in particular one for applications with a non-predominantly static load.

In reinforced concrete construction, steel bodies or rods are used to improve the static properties of concrete components, which absorb tensile forces and thus supplement the compressive strength of the concrete, so that the load-bearing capacity of the reinforced concrete components is improved. This is done in the form of steel bodies or rods made of reinforcing steel or round steel that are individually delivered to the construction site and interwoven there by hand, by installing welded uniaxial or biaxial reinforcing meshes or in segments with special shapes. Since uniaxial welded wire meshes can only absorb tensile forces in one direction, their longitudinal direction, it follows that two uniaxial welded wire meshes rotated by 90° to each other are necessary per reinforced concrete component so that it can absorb tensile forces and bending moments in every direction. The rebars produced by cold or hot deformation are usually not twisted, have an almost circular cross-section and a slopingly ribbed surface and possibly have longitudinal ribs.

Reinforcing steel bars are often up to 12 m long and usually have diameters of up to 40 mm, meaning that they can weigh several hundred kilograms.

For predominantly static loads, welded connections have been known and proven for a long time. Welded uniaxial reinforced steel mats, which can be laid on the construction site in a particularly time-saving manner, have a particular advantage. Corresponding machines have also been known for a long time, for example from EP 0 862 958

SUBSTITUTE SHEET (RULE 26) or PCT/DE2009/000298. The machine described in EP 0 862 958 for the production of uniaxial reinforcing steel bar mats has a lateral reinforcing steel bar feed to a mat former, with the already made-up reinforcing bars either being taken from a storage magazine or the reinforcing steel bars still to be made up being drawn off from coils by an automatic straightening cutting machine. be straightened and cut to length. The reinforcing steel bars fed into the mat former are positioned in the transverse direction to the mat by a transverse positioner and welded to flexible support strips by an automatic welding machine. The uniaxial reinforcing steel meshes have widths of up to 15 m and can contain reinforcing steel bars with different diameters and lengths. The thin steel strips with a certain width are used in order to be able to roll out the reinforcing steel bars in a directionally stable manner. The width of the tape ensures that it runs straight ahead and, after unrolling, the reinforcing steel bars lie exactly and stably in the previously calculated and planned position.

However, welded reinforcing steel bar mats are less suitable for reinforced concrete components and structures with loads that are not predominantly static, such as those that occur in civil engineering or structural engineering and in building construction. Such reinforced concrete components are, for example, those of road and railway bridges that are exposed to changing loads from moving traffic, those of offshore wind turbines that are stressed by waves and those of systems that experience dynamic excitations from gusty winds or vortex shedding, such as towers and masts or skyscrapers. Finally, concrete components in industrial plants such as crane runways, forklift ceilings or machine foundations fall under these structures that are not predominantly statically loaded. With all of these components Material fatigue due to permanent, highly cyclic alternating stresses with a high number of load changes. This type of stress is a major cause of damage to the aforementioned components and works.

Since the material fatigue behavior of welded joints is primarily concentrated locally on the weld seam - due to structural changes and a strong notch effect, there is a significant reduction in the fatigue strength of the steel - such a welded joint is known to be problematic in specialist circles.

For example, due to the notch effect of the weld, known welded reinforced steel mats or round bars do not achieve the fatigue strength prescribed by Eurocode 2 for use with loads that are not predominantly static; they are well below the Wöhler line for bars. For this reason, components with dynamic loads have so far mainly used individual rods, which have to be connected to one another by hand using thin wires, which is laborious and time-consuming on the construction site, so that this production of a dynamically loadable surface is correspondingly expensive due to the costly manual connection. If welded reinforced steel mats were used instead, the steel consumption increased significantly, since a sufficiently large amount of material was required.

EP 1 856 346 A1 discloses a machine for the production of uniaxial reinforcement mats, which feeds in the steel rods according to the same principle as described above, but does not weld them onto a large number of parallel, flat, flexible steel strips, but instead welds them at points that are axially spaced apart from one another which picks up rebar between two wires that are twisted together between the pick-up points. In this machine, two wires are twisted together to create a tightly twisted wire Wire strand, the individual strands of which are guided around a rebar that is fed in and which are accommodated in an eye formed in this way. In other words, instead of an endless strip of steel as described above, an in-situ generated, endless strand of wire is used for the permanent parallel arrangement of the reinforcing steel bars. A disadvantage of this machine and this method is the weak connection between the strand of wire and the reinforcing steel bar and the associated risk of the steel bar changing its position relative to the other steel bars of the uniaxial mat and the extremely low directional stability when unrolling the uniaxial mat on the construction site.

DE 44 36 610 A1 discloses a machine in which reinforcing bars are fastened to belts by means of wire, with one wire connector being arranged above the bar and one underneath the belt. A wire connector shoots a wire into an open diverting groove of the second wire connector, which diverts it back onto the first where the wire enters a funnel shaped hole. The first wire connector rotates a few turns until the end of the wire shears off.

The object of the present invention is therefore to specify a machine for the production of uniaxial reinforcing steel bar mats for a predominantly non-static load and a corresponding production method.

The device task is solved by the machine described below, the method task by a method described further below.

The machine according to the invention has a steel belt conveying device for conveying a plurality of mutually parallel and spaced support belts and a reinforcing bar conveying device on, the latter conveying individual reinforcing rods to form crossing points crossing onto the several support strips and preferably also positioning them longitudinally and axially, as well as several connecting units arranged to act at each crossing point, wherein a connecting unit has a binding wire conveying device which feeds a binding wire through a rotary unit wherein the rotary unit is movable relative to the fastener tape and the crossing reinforcing bar and is arranged on one side of the plane defined by both, and further comprises a binding wire guide unit which is arranged on the opposite side of the plane and which has a binding wire fed therein by the binding wire feeder is conveyed out and frictionally held in the opposite direction to the infeed direction, the rotating unit twisting and cutting the two strands of binding wire located on one side of the plane with one another, the rotating unit and the B inde wire guide unit to form a support band and rebar connecting wire loop closed closed such that support band and rebar are pressed together. As a result, a location-accurate, precise and durable connection of support band and reinforcing bar is achieved with great advantage, since the binding wire is guided cleanly and it does not have to be able to close a possible gap between the reinforcing bar and supporting band.

With great advantage, the reinforcement steel bars are fastened to broad, flat, flexible and track-stable support strips, in particular steel strips, which can be rolled out, but in a way that does not require the addition of material or the use of high-quality steel and is ideally suited for components with a non-predominantly static load. This is achieved by the wire loop according to the invention, which is looped around the support band and the conveyed-in reinforcing steel rod at their crossing points and connects them in a non-positive manner is. In addition, the use of non-weldable material, such as epoxy coated steel, galvanized material or stainless steel for the reinforcing rods and thus for the uniaxial mats is made possible by the wire binding according to the invention. A uniaxial reinforcing steel bar mat according to the invention therefore has a large number of such wire loops. The number of wire loops per reinforcement bar corresponds to the number of straps on which it is to be attached crossing them, so there are nx wire loops per n straps of the mat, where x is a number between 0 and n-2.

In an embodiment of the invention, it is provided that the machine has a cutting device, in particular a knife, preferably a stationary knife in the area of the rotating unit. After feeding in the binding wire of the required length, the rotary unit moves upwards away from the rebar, the binding wire being cut off by the appropriately shaped knife and at the same time being bent approximately against the direction of movement of the rotary unit due to the further movement of the rotary unit and the resistance of the knife , in particular even up to 180°. The bent free end of the binding wire produced in this way advantageously causes a pull-out resistance against being pulled out of the binding wire guide in the turning unit when turning, as a result of which the binding between the support strip and the reinforcing bar is tight and firm.

The fact that the machine bends a cut-to-length wire binding produced by it between the support strip and the crossing reinforcing bar from a predominantly orthogonal orientation to the plane to a predominantly parallel orientation to the plane advantageously avoids a risk of injury from otherwise protruding wire ends. With great advantage, the wire end of the wire loop is in one plane with the wire after bending Reinforcement bars and the support strips in the unrolling direction and thus protected against contact with a user.

In an embodiment of the invention, it is advantageously provided that the fastener tapes have guides for the binding wires, in particular openings and/or recesses, with the machine preferably producing these guides in situ. These guides advantageously create a guided, position-invariable binding wire loop around the node, which loop cannot loosen even if the support strip bends or buckles, for example when the uniaxial reinforcement mat is rolled up or down. The guides can be holes in the fastener tape - in particular oblong holes - or as indentations in the edge areas of the fastener tape or a combination of both.

The fact that a distance A between two guides is selected depending on the diameter of the rebar to be connected, in particular the distance A is smaller than the diameter of the rebar to be fastened, a strong bond is always achieved with great advantage for any different diameters of the rebar . A bar width adapted to the bar diameter prevents the bar from twisting. The web width can also be wider than the rod diameter. This results in a kind of grip on the staff with positive effects on position stabilization and a firm bond.

In a further development of the invention, it is provided that a length L of the binding wire 8 required for the connection varies depending on the diameter of the rebar to be connected in each case. This saves binding wire material on the one hand and on the other the generated twisted binding wire sections or free ends of the wire loops are always as short as possible and therefore protrude only a little.

The method according to the invention for producing a uniaxial reinforcement mat from a plurality of mutually parallel and spaced-apart reinforcing bars, which are oriented orthogonally to a plurality of mutually parallel and spaced-apart support strips and are attached to these, has the following steps: a) conveying in a reinforcing bar orthogonally parallel support strips spaced apart from one another along the longitudinal axes to produce a plurality of crossing points between the respective steel strip and the reinforcing bar, b) pressing the reinforcing bar onto the supporting strip in order to keep it in a tight position, c) feeding in a binding wire in the area of a crossing point around the steel strip and the reinforcing bar around to form a double binding wire strand on one side, d) cutting the binding wire to length and twisting the two binding wire strands into a twisted section.

In an embodiment of the method it is provided that step d) is followed by a step e) of bending the twisted section in or in the direction of the plane defined by the support strips and reinforcing bars.

According to the invention it is provided that a step of pressing the reinforcing bar onto the support strip takes place before, during or after steps c) and/or d). In a development of the method, step d) includes bending over the second free end of the binding wire produced by cutting it to length.

In an embodiment of the method, a step f) of introducing guides into the carrier tape is provided.

The invention is explained in more detail below with reference to the figures of an exemplary embodiment, with the same components being denoted by the same reference symbols. The figures show

1: a schematic view of a wire loop,

Fig. 2: a schematic sectional view of an embodiment of the machine in a first state and

Fig. 3: a schematic sectional view of an embodiment of the machine in a second state.

Fig. 1 shows a binding wire loop according to the invention around a crossing point 5 of support strip 2 - here a flat, flexible steel strip - and a reinforcing rod 4 - here a rod made of reinforcing steel. Oblong holes 17 can be seen in the support strip 2, the narrowest edge distance A from one another being smaller than a diameter D of the reinforcing bar 4. The two elongated holes 17 are here an embodiment of the guide 14 according to the invention for the binding wire 8 in the form of openings 15. The binding wire 8 is guided through the two elongated holes 17, the two binding wire strands 11 of which are twisted into a twisting section 18 after the method according to the invention has been carried out Twisting section 18 is also bent according to the invention, in particular approximately parallel to the plane of the support strip 2 and the reinforcing bar 4, so as to avoid later protruding from the concrete and injuries to a user. Taking level is not strictly mathematical to understand two-dimensional plane, but rather the three-dimensional plane formed by the support strip 2 and rebar 4. The width of the support strips 2 of a uniaxial reinforcement mat is chosen so that it can be rolled out with safe straight running.

According to the invention, the rebars 4 are selected from those with diameters between 6 mm and 40 mm, the distances between the parallel rebars 4 of a uniaxial reinforcement mat being freely selectable according to the requirements of the respective use of the uniaxial reinforcement mat. This is done by computer-controlled, optimized planning with regard to length, position, spacing, diameter, material, etc. A minimum spacing between two adjacent reinforcing rods 4 is preferably maintained in order to achieve security against crossing over.

The edge distance A of the web of the support band 2 remaining between the elongated holes 17 is adapted to the rod diameter D to be bound. In particular, it is smaller or the same width as this one. The result of this is that the binding does not loosen even if the support band 2 bends or buckles, precisely during the rolling up during manufacture. By adjusting the size of the edge distance A, a firm bond is always achieved for any number of different diameters D of the reinforcing bars 4 . It also prevents the rebar 4 from twisting about its longitudinal axis. According to the invention, this distance A is also selected to be wider than the rod diameter D. This results in a kind of clasping of the reinforcing bar 4 with positive effects on the stabilization of the position and at the same time a firm bond.

2 shows an embodiment of the invention in a first operating state. In this, a rebar 4 is already on a A plurality of fastener tapes 2 are conveyed and, if necessary, positioned in relation to them in its axial direction. The support band conveyor 1 and the reinforcing bar conveyor 3 are shown purely schematically, the crossing point 5 is located below the illustrated reinforcing bar 4, the rounded binding wire guide unit 10 being arranged below the crossing point 5 and supporting band 2 and reinforcing bar 4 preferably partially encompassing. A binding wire conveyor 7 is shown schematically. This conveys the binding wire 8 through the rotary unit 9 in the direction of the crossing point 5. The connection unit 6 according to the invention consists of the components of the binding wire conveying device 7, the rotary unit 9 and the binding wire guide unit 10. The rotary unit 9 has a U-shaped body through which the Binding wire 8 is performed.

In this embodiment, the carrier tape 2 is guided through a punching unit 19, shown schematically, which introduces guides 14 in the form of elongated holes 17 into the carrier tape 2 in situ. According to the invention, the guides 14 can also be, for example, triangular or dovetail-like recesses in the edge regions of the support strip 2, in particular recesses offset diagonally to the longitudinal axis of the support strip 2 or openings 15 shaped differently than slots. As an alternative to this, a carrier tape 2 already provided with guides 14 during production is used according to the invention.

The operating state shown is the one before the connection. In order to create the wire loop, the turning unit 9 and the binding wire guide unit 10 are moved close to one another, so that the binding wire 8 is fed into the wire guide unit 10 below the crossing point 5 of the support band 2 and the reinforcing bar 4 without a gap and is fed out again in the opposite direction to the feeding direction. a specific overhang length being selected depending on the diameter D of the rod 4 to be fastened after it has been conveyed out.

FIG. 3 shows a second operating state in which the connection is made by creating a tightened wire loop. The rotating unit 9 is raised above the rod cross section. Here, the binding wire is cut off by means of a knife 13 as a cutting device 12 in front of the rotary unit 9, viewed in the conveying direction of the binding wire 8, and the second free wire end thus produced, preferably due to the shape of the knife 13, is simultaneously bent by the latter, preferably in the direction of the reinforcing bar 2 When rotating the rotary unit 9, this bent end creates a pull-out resistance against pulling out due to the shortening of the protruding wire length resulting from the twisting. This makes the binding tight and strong. The rotation against the pull-out resistance allows the two strands of binding wire 11 to be twisted against one another, creating a twisting section 18. The twisting ultimately causes the bent end to slip out of the rotary unit 9. After the holder has been released, the rod is now free. During binding, the rod and the band are additionally pressed according to the invention and thus held in a close position.

When the rod is transported further, the twisting section 18 is also bent over so as not to protrude too far. Otherwise, the binding could protrude from the concrete in the upper layer or cause injuries. REFERENCE LIST

1 conveyor belt conveyor

2 strap

3 rebar conveyor

4 rebar

5 crossing point

6 connection unit

7 Binding Wire Feeder

8 binding wire

9 turning unit

10 binding wire guide unit

11 strand of binding wire

12 cutting device

13 knives

14 leadership

15 opening

16

17 slotted hole

18 twisting section

19 punch unit

20 binding wire channel

A edge distance

D diameter

Claims

PATENT CLAIMS Machine for the production of uniaxial reinforcing steel bar mats, having a steel belt conveyor device (1) for conveying a plurality of carrier belts which are parallel to one another and spaced apart from one another

(2) and a rebar conveyor

(3), the latter being single reinforcing bars

(4) conveying and preferably also longitudinally axially positioned to form crossing points (5) crossing onto the plurality of fastener tapes (2), and several, at each crossing point

(5) operatively arranged connecting units (6), one connecting unit (6) having a binding wire feed device (7) which feeds a binding wire (8) through a turning unit (9), the turning unit (9) rotating relative to the fastener tape (2 ) and the crossing rebar (4) is movable and arranged on one side of the plane defined by the support strip (2) and the rebar (4), the connecting unit

(6) further comprises a binding wire guide unit (10) disposed on the opposite side of the plane and fed into it by the binding wire conveying means

(7) conveying out the fed-in binding wire (8) in the opposite direction to the feed direction and holding it by friction, the turning unit (9) twisting the two strands of binding wire (11) on one side of the plane together and cutting them to length, characterized in that the turning unit (9) and the binding wire guide unit (10) to form a wire loop (2) connecting the reinforcing bar (4) are closed on one another such that the supporting band (2) and reinforcing bar (4) are pressed onto one another. Machine according to claim 1, characterized in that the rotating unit (9) has a cutting device (12), in particular a knife (13). Machine according to Claim 1 or 2, characterized in that it bends a cut-to-length wire binding produced by it between the support strip (2) and the crossing reinforcing bar (4) from a predominantly orthogonal orientation to the plane to a predominantly parallel orientation to the plane. Machine according to claim 1, 2 or 3, characterized in that the guides (14) are openings (15) and/or recesses, the machine preferably being in-situ generating these guides (14). Machine according to one of the preceding claims, characterized in that the openings (15) are designed as oblong holes (17). Machine according to one of the preceding claims, characterized in that an edge distance (A) between two guides (14) is selected depending on the diameter of the respective reinforcing steel bar (4) to be connected, in particular the edge distance (A) is smaller than a diameter (D) of the reinforcing steel bar (4) to be fastened. Machine according to one of the preceding claims, characterized in that it has a length (L) of binding wire required for the connection

(8) varies depending on the diameter of the reinforcing steel bar (4) to be connected. Method of manufacturing a uniaxial reinforcing mesh from a plurality of mutually parallel and apart - 16 - spaced-apart rebars, which are oriented orthogonally to and attached to a plurality of mutually parallel and spaced-apart support bands, comprising the following steps: a) feeding in a rebar orthogonally to the longitudinal axes of parallel support bands spaced apart from one another to produce a plurality of crossing points between the respective steel strip and the reinforcing bar, b) pressing the reinforcing bar onto the supporting strip to keep it in a tight position, c) feeding in a binding wire in the area of a crossing point around the steel strip and the reinforcing bar, forming a double strand of binding wire on one side, d) cutting the Binding wire and twisting the two strands of binding wire thus produced to form a twisted section.

9. The method according to claim 8, wherein step d) is followed by a step e) of bending the twisting section in or in the direction of the plane defined by support strips and reinforcing bars.

10. The method according to claim 8 or 9, wherein step b) of pressing the reinforcing bar onto the support strip takes place before, during or after steps c) and/or d).

11. The method according to any one of claims 8 to 10, in which step d) comprises bending over the second free end of the binding wire produced by cutting it to length.

12. The method according to any one of claims 8 to 11, in which a step f) of introducing guides into the fastener tape takes place.