EP2897744A1

EP2897744A1 - Device and method for automatically twisting metal wires, in particular for connecting adjacent, preferably mutually intersecting structure elements

Info

Publication number: EP2897744A1
Application number: EP13741751.5A
Authority: EP
Inventors: Günther Horn
Original assignee: Wobben Properties GmbH
Current assignee: Wobben Properties GmbH
Priority date: 2012-09-19
Filing date: 2013-07-25
Publication date: 2015-07-29
Anticipated expiration: 2033-07-25
Also published as: CA2881754A1; PT2897744T; AU2013320549B2; KR101727418B1; MX2015002768A; ES2693346T3; CL2015000677A1; IN2015DN01226A; CN104640647B; MX353873B; US9808854B2; ZA201500906B; BR112015005938A2; DE102012216831A1; CA2881754C; CN104640647A; RU2600779C1; DK2897744T3; KR20150059764A; NZ705009A

Abstract

The invention relates to a device, a method and a use of said device (1) for automatically twisting metal wires. The invention relates, in particular, to a device of this kind for connecting adjacent, preferably mutually intersecting structure elements, comprising a wire feed for feeding wire, preferably endless wire, into the device, a wire guiding arch (5), which has an optionally releasable and closable opening (7) and which is provided in order to guide the fed wire in the closed position along the wire guiding arch from a first side (9) of the wire guiding arch to a second side (11) of the wire guiding arch lying opposite the opening, a traction carriage (23), which is provided in order to detect the fed wire on the first side (9) of the wire guiding arch and to pull the wire towards the second side of the wire guiding arch, and a twisting unit (25), which is provided in order to detect the fed wire on both sides of the wire guiding arch and to twist the wire by means of a rotational movement.

Description

Device and method for automatic twisting of metal wires, in particular for connecting adjacent, preferably crossing one another

structural elements

The present invention relates to a device for automatically twisting metal wires, in particular for connecting adjacent, preferably crossing, structural elements. In the context of the invention, a structural element is understood to mean an elongated body which has a round or polygonal, for example quadrangular, cross section. Examples of such structural elements are, for example, tubes, rods or carriers, as they are widely used in all sectors of industry. Also covered by the term structural element are wire rope bundles, so-called strands, or prestressing strands, which are used inter alia for the production of reinforcing baskets for prestressed concrete elements. A typical application for devices of the type mentioned is the production of such reinforcing cages, for example. For prestressed concrete elements. Reinforcement baskets have a grid-like structure made of (steel) strands. The lattice-like structure is achieved by interposing strands in a first direction and strands in a second direction crossing each other. In the area in which they intersect, the so-called twisting area, the position of the strands is fixed to each other by means of a metal wire. The metal wire is wrapped around the twist portion of the strands, forming a loop. The two ends of the Wires are then twisted against each other several times until the loop of the wire is sufficiently narrow to fix the two intersecting strands or generally the intersecting structural elements to each other.

As an alternative to a crossing arrangement of a plurality of structural elements, generally adjacent structural elements are often fastened by means of twisting wires around the adjacent structural elements. The procedure, with the exception of the other orientation of the structural elements, essentially takes place as described above. For example, since reinforcing baskets consist of a plurality of strands and consequently also a large number of twisting areas is present, many wires have to be twisted for the production of a reinforcing basket. So far, this is done exclusively in manual work. Since the wires to be used for twisting must also have a certain stability, this activity is exhausting for the corresponding persons and also very time-consuming. Due to the manual nature of the twisting, unevenly twisted wires are also produced. Although this is not serious from the point of view of quality assurance due to the large number of conversions made, a higher repeat accuracy would be desirable when twisting wires over adjacent, preferably intersecting, structural elements. Accordingly, it is an object of the present invention to provide an apparatus and a method which overcomes the disadvantages described above. The invention solves the underlying object in a device of the type mentioned in that it is designed according to the features of claim 1. The invention solves the problem in particular by providing a device for automatic twisting of metal wires, in particular for connecting adjacent, preferably crossing structural elements, with a wire feeder for feeding wire, preferably endless wire, into the device, a wire guide arc which selectively releases one and closable opening and adapted to guide the supplied wire in the closed position along the Drahtführungsbo- gene from a first side of the wire guide arc to a relative to the opening opposite the second side of the wire guide arc, a Zugschlitten which is adapted to to grasp the supplied wire on the first side of the wire guide bow and to the second side of the wire guide and a twisting unit which is adapted to detect the supplied wire on both sides of the wire guide arc and to twist by means of a rotational movement. Advantageous embodiments and preferred embodiments and embodiment of the invention will become apparent from the dependent claims and the description below. The invention makes use, in particular, of the finding that an automation of the displacement significantly contributes to fatigue-free work, since, in particular, twisting is cumbersome. However, the invention goes even further by providing a device which also allows the wire to be passed around the displacement area of two or more adjacent, preferably intersecting structural elements, thereby achieving a significant acceleration of the overall operation. The Zusammenspie! An automated routing of the wire and automated twisting is based on the following guiding principles: The wire is moved along a wire guide arc to ensure a high repeat accuracy with regard to the loop formation through the wire. In order to be able to arrange the wire guide arc, which is formed on the device, in the Verdrlllungsbereich enclosing manner, an opening of the wire guide arc is provided. This allows even in hard to reach Verdriilungsbereichen, as can be found, for example, reinforcement cages for prestressed concrete components, a simple approach of the device to the Verdriliungsbereich, embracing the Verdrillungsbereiches with an open wire guide bow and enclosing the Verdriilungsbereiches by closing the opening. The operation is similar to a pair of pliers, for example. Furthermore, the invention is characterized in that the wire along the wire guide arc is pulled by the Zugschlitten. The inventive design of a pulling guide the wire along the wire guide arc is applicable to soft wires that allow better twisting than wires made of hard material .. The device of the invention thus allows by opening and closing the wire guide arc, the Drahtführungsbogen- around the Verdrlllungsbereich two Laying structural elements, and the movable Zugschiitten then makes it possible to guide the supplied on one side of the wire guide arc wire with a closed wire guide arc around the Verdriliungsbereich along the wire guide arc. Finally, the twisting unit can then pick up the wire around the twisting area of the pulling carriage detect both sides of the twisting region or on both sides of the wire guide arc and, for example by means of a rotary drive, perform the twisting. Preferably, the wire guide arc is tongs-like, and the selectively releasable and closable opening is proximal to the device. The invention is advantageously further developed in that the twisting unit has a first wire feedthrough hole and a second wire feedthrough hole, the wire feed being adapted for this purpose Thus, even when feeding the wire in the direction of the wire guide arc, the later detection of the wire by the twisting unit can be prepared, and by passing through the insertion hole, the wire is already detectable by the twisting unit the pulling carriage is configured to pass the wire drawn toward the second side of the wire guide arc through the second wire passing hole such that the wire forms a loop from the first to the second passage The advantage of this embodiment is in particular the preparation of the detection by the twisting unit on the second side of the wire guide arc in one operation by means of the Zugschiittens while leading the wire along the wire guide arc. As soon as the loop is formed by the wire, it is immediately inserted and guided into the second wire feed-through hole of the twisting unit.

In a preferred embodiment, the device according to the invention comprises a clamping device, which is preferably arranged on the first or second side of the wire guide arc and which is arranged for holding the wire passed through the first wire feedthrough hole or for holding the wire passed through the second wire feedthrough hole. In particular, the clamping device is adapted to fix the wire after forming the loop over the twisting region of the two structural elements, so that the twisting can be further prepared by the screwing unit. Further preferably, the device according to the invention comprises a drive means for wire conveying, wherein the drive means is adapted to promote the carried by the second Drahtdurchführungsioch held by the Kiemmeinrichtung wire to shorten the loop formed to a predetermined extent. When twisting the detected wire by means of the twisting unit, the distance between the constriction created by the rotation and the structure elements to be twisted decreases with each revolution. In order to achieve a sufficient fixation of the structural elements, a certain minimum number of twists is required. On the other hand, in order to achieve as little wire consumption as possible, the number of twists carried out should not exceed a maximum amount. Therefore, it is preferable to limit and define the distance between the twisting unit and the structural members by shortening the wire loop before twisting. It has been found to be particularly preferable to set a loop length which leaves a clearance between the twisting unit and the structural elements to be connected which corresponds to the gauge between the first wire feed-through hole and the second wire feed-through hole.

As a reference point for the twisting unit, in determining the distance, the plane in which the points at which the wire on the first and second sides of the wire guide arc is grasped by the twisting unit is assumed. This plane is preferably perpendicular to the axis of rotation of the twisting unit. It is alternatively preferred to assign the drive means of the wire feed, wherein the drive means is adapted to promote the wire either in the feed direction or counter to the feed direction. The conveying direction is primarily dependent on which of the two sides of the wire guide arc, the clamping device is arranged and holds the wire.

According to a further preferred embodiment, the drive means to a drive member which is driven by a motor and is coupled to the Zugschliiten such that the Zugschlitten selectively from the first side of the wire guide bow to the second side of the wire guide arc out and from the second side of the wire guide arc to the first side of the wire guide bow is movable. According to a further preferred embodiment, the twisting unit has two gear wheels arranged coaxially with one another, through which the first and second leadthrough pass each extend completely therethrough, and wherein the two gear wheels can be driven both in opposite directions and in the same direction. Preferably, the two coaxially arranged gears are arranged directly adjacent to each other. An opposite driving of the two gears preferably causes jamming of the wire passing through the first and second wire penetrating holes. This allows the detection of the wire by the twisting unit. The drive is preferably realized by means of a servo motor. As soon as a sufficient clamping of the wire has been achieved by the counter drive of the gears, the two gears are preferably drivable in the same direction, in such a way that the clamping is maintained while the gears rotate in synchronism to the twist by means of a rotation of the two Wire feedthrough holes around a common axis of rotation bring about. Further preferably, the device according to the invention comprises a cutting body, which is arranged for separating the wire within the device and adapted to separate the wire on the first side of the wire guide arc and / or on the second side of the wire guide arc. In this way, the separation of the wire is made possible before twisting, without having to carry separate cutting tools with him. The device according to the invention thus permits, in a single, continuous operation, the feeding of wire, wrapping of the wire around a composite of structural elements to be twisted, separation of the twisted wire section from a feed-side wire section, and finally twisting of the wire. The cutting body is preferably formed as a sharp-edged cutting edge within the device, which is arranged adjacent to the wire passed through the device. Preferably, one or both of the gears of the twisting unit have the cutting edge (s) which is or are formed on the one or more gears such that the separation takes place when the twisting movement begins. The invention further relates to a method for automatically twisting a metal wire for connecting two or more adjacent, preferably themselves crossing structural elements. The invention solves the underlying task mentioned in such a method with the following steps:

Providing two or more adjacent, preferably crossing, structural elements,

Feeding the wire into a device according to one of the preferred embodiments described above,

Passing a crossing region of the structural elements through a released opening of a wire guide arc of the device,

Closing the opening of the wire feed arc so that the twist region of the structural elements is enclosed by the wire guide arc,

Detecting the supplied wire by means of a pull slide

Drawing the supplied wire by means of the pull slide with the wire feed arc closed along the wire feed arc from a first side of the wire feed arc to a second side of the wire feed arc opposite the opening;

Detecting the supplied wire on both sides of the wire guide sheet mitteis a Verdriileinheit, and

Twisting the detected wire by means of a rotational movement of the twisting unit.

With regard to the underlying findings and advantages according to the invention, reference is made to what has been said above with reference to the device according to the invention. The method according to the invention is preferably further developed in that the detection of the supplied wire by means of a twisting unit comprises one or both of the steps: passing the supplied wire through a first wire through-hole, preferably by means of a wire feed of the device,

Passing the wire drawn to the second side of the wire guide arc such that the wire forms a loop around the structural members from the first to the second wire feedthrough hole. Further preferably, the method comprises the step:

Holding the wire passed through the first wire feed-through hole or the wire passed through the second wire feed-through hole by means of a clamping device of the device, According to a preferred embodiment of the method, this further comprises the step:

Conveying the wire passed through the second wire feedthrough hole and held by the clamping device such that the formed loop is shortened to a predetermined extent. Further preferably, in the method according to the invention, the step of detecting the supplied wire on both sides of the wire guide arc by means of the twisting unit comprises:

oppositely driving two coaxially arranged gears through which the first and second wire penetrating holes respectively extend completely therethrough such that the passed wire is clamped, and

wherein the step of twisting the detected wire by means of a rotational movement of the twisting unit comprises:

a co-driving of the two gears with clamped wire. Further preferably, the method according to the invention comprises the step:

- Disconnecting the twisted wire on the first and / or on the second side of the wire guide arc by means of a cutting body within the device. The invention further relates to the use of a device according to one of the preferred embodiments described above for the automatic twisting of metal wires, in particular for connecting adjacent, preferably crossing structural elements, for producing a reinforcement cage for a tower element of a wind turbine. The device has in particular:

a wire feeder for feeding wire, preferably an endo wire, into the apparatus, a wire guide arc having a selectively openable and closable opening and arranged to move the supplied wire in the closed position along the wire guide arc from a first side of the wire guide arc to a wire guide arc; relative to the opening opposite the second side of the wire guide arc, a pulling carriage adapted to catch the supplied wire on the first side of the wire guide arc and pull it towards the second side of the wire guide arc, and a twisting unit adapted thereto is to detect the supplied wire on both sides of the wire guide arc and to twist by means of a rotary motion. In this case, the reinforcing cage has, as the first and second structural elements, a plurality of first and second prestressing strands which are arranged to cross one another. The tension strands can optionally be intertwined, which is the Positioning the tensioning strands before twisting the wire facilitates and increases the stability of the basket. The advantages of the above developments and preferred embodiments of the device according to the invention also apply to the developments and preferred embodiments of the method according to the invention and the development of the use according to the invention. The invention will be described in more detail below with reference to the accompanying figures and with reference to an embodiment. Hereby show:

1 is a perspective view of a device according to the invention for twisting metal wires,

FIG. 2 shows a side view of the device according to FIG. 1 in another operating state, FIG.

Fig. 3 is a side view of the device of FIG. 1 in partial sectional view and

4 shows a partially transparent spatial representation of a detail of the device according to FIG. 1. FIG. 1 shows a device 1 for the automatic twisting of metal wires. The device 1 has a base body 3. On the main body 3, a wire guide sheet 5 is arranged at a proximal end of the device 1. The wire guide sheet 5 has a substantially centrally disposed between a first side 9 of the wire guide sheet 5 and a second side 11 of the wire guide sheet 5 closable and releasable opening 7. In the embodiment shown, the first side 9 of the wire guide arc is fixed relative to the base body 3, while the second side 11 of the wire guide arc 5 is deflectable by means of a lever kinematics 15 such that the opening 7 from the closure position shown in Fig. 1 in a release position is moved (Fig. 2). The lever kinematics 15 is driven in the embodiment shown by means of a pneumatic cylinder 17 .. The wire guide arc 5 is formed substantially like a pliers and has in the interior of the two sides 9, 11 of the wire guide arc a region 27 for receiving adjacent, preferably crossing structure elements. The wire guide arc 5 has a substantially 13 extending along the entire arc slot. The slot 13 divides the first side 9 of the wire guide arc in two Tellbögen 9 a, 9 b. in an analogous manner, the slot 13 divides the second side 11 of the wire guide arc 5 into two partial arcs 11 a, 11 b. The slot 13 is adapted to receive a Zugschiitten 23 which is movable along the wire guide arc and guided by a guide groove 29 arranged inside the wire guide arc.

At a wire guide arc 5 opposite end of the region 27, a twisting unit 25 is arranged. The twisting unit 25 is adapted to receive and grasp the wire guided along the wire guide arc 5 and is further adapted to twist it by rotation about a rotation axis X. At a wire guide arc 5 opposite, distal end of the base body 3, a drive chain 19 is arranged, which extends partially from the housing or base 3 of the device 1 out. The drive chain has a plurality of guide pins 21 which are adapted to stabilize and guide the drive chain 19 under shear load. With reference to the other figures, the same reference numerals are given for similar or identical elements. With regard to the description of these elements, reference is therefore made to the other figures in each figure. In the state shown in Fig. 2, the wire guide arc 5 is brought by lateral pivoting of the second side 11 of the wire guide arc in a position in which the opening 7 of the wire guide arc 5 is released. The opening allows embracing two or more adjacent, preferably crossing structural elements, for example two or more tension strands to twist them.

In the operating state shown in FIG. 2, the pulling slide 23 is further away along the first side 9 of the wire guiding arc 5 in the direction of the second side 11 of the wire guiding arc 5. Fig. 3 allows a view of the inner workings of the device 1. The wire to be twisted is supplied in a plurality of feed channels 31a, 31b by means of a driving member 49 in the direction of the wire guide sheet 5. The Antriebsmittei 49 has a piston 50, which deflects a first coupling member 52 and a second coupling member 53 such that a clamping member 51 through which the wire is also passed, this clamps on the Antriebsmittei 49. As a result, a promotion of the wire in the feed direction and counter to the feed direction is possible. The pulling carriage 23 is coupled to the drive chain 19. The movement of the drive chain 19 in both drive directions is ensured by means of a drive pin 33 which is drivably mounted on the main body 3 of the device. By appropriate drive of the drive chain 19, the pull slide 23 is guided by means of the groove 29 and moved from the position shown in Fig. 3 along the wire guide arc on the opposite second side 11 of the wire guide arc 5. This is preferably done when the pull slide 23 has detected the wire in a clamping device 41 and clamped. The twisting unit 25 (FIGS. 3, 4) has two toothed wheels 37, 39 which are arranged coaxially with one another and directly next to one another, through which a first wire feedthrough hole 43 and a second wire feedthrough hole 45 extend completely through. The first and second Drahtdurchführungsioch 43, 45 are preferably arranged diametrically opposite with respect to the axis of rotation of the two gears 37, 39 and adapted to receive the wire. The wire is fed by means of the drive means 49 through the first Drahtdurchführungsioch 43 on the first side 9 of the wire guide arc 5 and passed by the Zugschlittens 23 on the second side 11 of the wire guide arc 5 through the second Drahtdurchführungsioch 45. In a completed state (through the second Drahtdurchführungsioch 45), a second clamping device 46 is adapted to clamp the wire, so that a shortening of the loop by conveying the wire back through the drive means 49 when moving back from the second side 11 of the wire guide sheet 5 in the direction of the first Page 9 can be done. The drive and further details of the twisting unit 25 are also shown in Fig. 4. The clamping device 41 of the pulling carriage 23 is preferably designed such that a first slide 36 for detecting and clamping the wire by the pulling carriage 23 deflects a second slide 38 when deflected from a release position, which causes a verkiemmung the wire. The coupling of the first slider 36 with the second slider is preferably accomplished by means of two matched slanting planes which allow the slides 36, 38 to slide together and define the direction of movement of the slides. The first slider 36 is preferably arranged on the pulling carriage arranged us so that it is moved on movement of the Zugschiittens 23 from the first side to the second side toward a shoulder 40. The heel 40 and the slider 36 are first brought into contact with each other as the traction carriage 23 approaches its end position on the second side. Upon further approach of Zugschiittens 23 to its final position on the second side of the paragraph 40 presses against the slide and displaces it from its relative position on the Zugschlitten 23 in the direction of its (shown in Figure 3) release position. As a result, a transfer of the wire to the second clamping device and a return of the pulling carriage 23 is made possible without wire entrainment. Fig. 4 shows the arrangement of the two gears 37, 39 relative to the Zugschütten and the wire guide sheet 9 in a spatial representation. The first gear 37 of the twisting unit 25 is driven by means of a first gear 47. The second gear 39 of the twisting unit 25 is driven by means of a second gear 48. Gear 47 and 48 are connected by torsion shafts 55, 57 each having a servomotor. The first gear 37 and the second gear 39 are by means of the gears 47, 48 either opposite or can be driven in the same direction. By driving the gears 37, 39 in opposite directions, the respective portions of the wire penetrating holes 43, 45 are slightly twisted against each other, resulting in jamming of the wire passed through the wire penetrating holes 43, 45. In the clamped state, the motors are preferably driven to drive in unison the gears 37, 38 erfoigt, such that the clamping of the wire is maintained. Preferably, the wire feedthrough holes 43,45 are formed as elongated holes, wherein the elongated holes extend along curved paths. Preferably, the cam tracks in the first gear 37 are not congruent with the cam tracks in the second gear 47. Particularly preferably, the curved paths are formed as circular arc sections, wherein the circular arc sections associated circle centers are arranged eccentrically with respect to the respective gear. This ensures that the clamping is made particularly gentle against each other in relative movement of the gears, since the slots formed as wire guide holes only gradually from their congruent position with each of the other gear associated portion of the wire feedthrough hole are brought.

According to a preferred embodiment, the gears 37,47 each have a plurality of holes sets of wire feedthrough holes. It is expected that over time, wear on the punch cards will occur due to the clamping force application. Gear wheels with a plurality of sets of holes then have the advantage that no complete change is necessary, but only the "advancement" of the gear wheels to the next set of holes Fig. 4 executed by a rotatable pin which can taper or close the passage for the supplied wire.

With reference to Figures 1 to 4 is a brief outline of the

Operation of the device 1 according to the invention given. After two or more structural elements, such as tension strands, have been provided, adjacent to each other, preferably crossing one another, if attachment of the two structural elements in the area of the crossing (hereinafter twisted area) is desired, the device 1 approximated to the twist area. For embracing the Verdriliungsbereiches of the two structural elements, the second side 11 of the wire guide arc 5 is opened by actuation of the lifting kinematics 15 such that the opening 7 is released. The adjacent, preferably intersecting, structural elements are inserted into and around the inner portion 27 of the wire guide arch. In preparation for looping, the wire is moved in the direction of the draw slot 23 either manually or by a drive means such as the drive means 49; fed. The wire is grasped by the pull slide 23 by means of a clamping device 41 and guided from the first side 9 of the wire guide bend 5 in the direction of the second side 11 of the wire guide bend. Optionally, the traction slide 23 is already partially moved along the first side 9 of the wire guide arc 5 before the wire guide arc 5 has completely settled around the structural elements and the opening 7 is closed again. When the opening 7 is closed, the pulling slide 23 is completely on the second side 11 of the wire guide bow method, where a transfer of the detected by the Zugschiitten 23 wire to the second feedthrough opening 45 of the twisting unit 25 takes place. Even before feeding the wire, it has also been passed through the first wire guide opening 43 of the twisting unit 25. Subsequently, the wire forming a loop is clamped by means of a wire clamp 46. The Zugschütten 23 is released from the wire and moves partially or completely back to its original position on the first side of the wire guide arc 5 (for example, as shown in FIG. 1) back.

Before Verdriileinheif 25 performs the twisting of the wire by rotation of the two wire feedthrough openings 43, 45 around each other, preferably the length of Drahttsaufe formed is shortened to a predetermined level, which is dependent on the distance between the two wire feedthrough openings 43, 45 and the required minimum loop length, the again according to the thickness of the structural elements. The shortening of the loop is preferably carried out by means of the drive means 49 or by re-detecting the wire through the Zugschütten 23, if this is not fully back to the position on the first page 9 of the wire guide sheet 5 (Fig. 1), and subsequent return by means of the traction carriage. When the loop has reached the predetermined length, the gears 37, 39 are first driven in opposite directions by means of the gears 47, 48 and the motors connected to them, until a sufficient clamping within the twisting unit 25 is obtained. In this locked state, the gears 37, 39 are then driven in unison, and the wire is separated within the device 1, preferably by means of a cutting body, for example by means of one or more cutting edges on the gears, the twisting unit 25 performs a Verdrillbewegung following the separation around the axis X out. After the desired number of revolutions, the opening 7 is released again and the device 1 is removed from the Verdriilungsbereich to perform, for example, a next Verdrilloperation. As can be seen from the above descriptions, the whole process of looping and twisting is automated, which is a significant labor hassle for operators.

Claims

Claims 1. Device (1) for automatically twisting metal wires, in particular for connecting adjacent, preferably crossing structural elements, with a wire feeder for feeding wire, preferably endless wire, into the device,

a wire guide arch (5), which has an opening (7) that can be selectively released and closed and is designed to move the supplied wire in the closed position along the wire guide arch from a first side (9) of the wire guide arch to one, relative to the Opening opposite, second side (11) of the wire guide arch to guide,

a pulling carriage (23), which is designed to grasp the supplied wire on the first side (9) of the wire guide sheet and pull it towards the second side of the wire guide sheet, and

a twisting unit (25), which is designed to grasp the supplied wire on both sides of the wire guide sheet and to twist it by means of a rotational movement.

2. Device according to claim 1,

wherein the wire guide arch (5) is designed like a pair of pliers and the opening (7) that can be selectively released and closed is arranged proximally on the device (1).

3. Device according to claim 1 or 2,

wherein the twisting unit (25) has a first wire feedthrough hole (43) and a second wire feedthrough hole (45), and wherein the wire feeder is designed to pass the fed wire through the first wire feedthrough hole.

4. Device according to claim 3,

wherein the pull slide (23) is designed to guide the wire drawn towards the second side (11) of the wire guide arch through the second wire feedthrough hole (45) in such a way that the wire forms a loop from the first to the second wire feedthrough hole.

5. Device according to one of the preceding claims,

with a clamping device (41, 46), which is preferably arranged on the first or second side of the wire guide sheet, and which is used to hold the wire guide through the first The wire passed through the wire feedthrough hole is set up, or is set up to hold the wire passed through the second wire feedthrough hole.

6. Device according to claim 5,

with a drive means (31, 49) for conveying wire,

wherein the drive means is designed to convey the wire passed through the second wire feedthrough hole (45) and held by the clamping device (46) in order to shorten the loop formed to a predetermined dimension,

7. Device according to claim 6,

wherein the drive means (49) is assigned to the wire feed and is designed to convey the wire either in the feed direction or against the feed direction,

8, device according to claim 6,

wherein the drive means (33) has a drive member which can be driven by a motor and is coupled to the pull chute in such a way that the pull carriage can selectively move from the first side of the wire guide sheet to the second side of the wire guide sheet and from the second side of the wire guide sheet to the first Side of the wire guide bow can be moved.

9. Device according to one of the preceding claims,

wherein the twisting unit has two coaxially arranged gears (37, 39), through which the first and second wire feedthrough holes each extend completely, and

whereby the two gears can be driven in opposite directions or in the same direction.

10. Device according to one of the preceding claims,

with a cutting body which is arranged to separate the wire within the device and is designed to separate the wire on the first side of the wire guide arch and / or on the second side of the wire guide arch,

11. Method for automatically twisting a metal wire for connecting two or more adjacent, preferably crossing, structural elements, comprising the steps:

Providing two adjacent, preferably crossing structural elements, Feeding the wire into a device according to one of claims 1 to 10, passing through a crossing area of the structural elements through a released opening of a wire guide arc of the device,

Closing the opening of the wire feed arch so that the crossing area of the structural elements is enclosed by the wire guide arch,

Grasping the fed wire using a pull carriage

Pulling the fed wire by means of the pulling slide with the wire feed arch closed along the wire feed arch from a first side of the wire feed arch to a second side of the wire feed arch opposite the opening,

Capturing the fed wire on both sides of the wire guide sheet using a twisting unit, and

Twisting the captured wire by means of a rotational movement of the twisting unit.

12. The method according to claim 11,

wherein detecting the supplied wire by means of a twisting unit comprises one or both of the steps:

Passing the supplied wire through a first wire through hole, preferably by means of a wire feed of the device,

Passing the wire drawn toward the second side of the wire guide sheet such that the wire forms a loop from the first to the second wire feedthrough hole around the structural elements.

13. Method according to claim 12,

full:

Holding the wire passed through the first wire feedthrough hole or the wire passed through the second wire feedthrough hole by means of a clamping device of the device.

14. Method according to claim 13,

full:

Conveying the wire passed through the second wire feed-through hole and held by the clamping device in such a way that the loop formed is shortened to a predetermined size.

15. Method according to one of claims 11 to 14,

wherein the step of grasping the fed wire on both sides of the wire guide sheet by means of the twisting unit comprises:

a counter-rotating drive of two coaxially arranged gears, through which the first and second wire feed-through holes each extend completely, such that the wire passed through is clamped, and

a simultaneous driving of the two gears with clamped wire.

16. Method according to one of claims 11 to 15,

comprising the step:

Separating the wire on the first and/or second side of the wire guide sheet by means of a cutting body within the device before the twisting step.

17. Use of a device (1) for automatically twisting metal wires, in particular for connecting adjacent, preferably crossing, structural elements, for producing a reinforcement cage for a tower element of a wind turbine, the device being designed according to one of claims 1 to 10, in particular comprising:

a wire feeder for feeding wire, preferably endless wire, into the device,

a wire guide arch (5), which has an opening (7) that can be selectively released and closed and is designed to move the supplied wire in the closed position along the wire guide arch from a first side (9) of the wire guide arch to one opposite the opening to guide the second side (11) of the wire guide sheet,

a twisting unit (25) which is designed to grasp the fed wire on both sides of the wire guide sheet and to twist it by means of a rotational movement, and wherein

the reinforcement cage has a plurality of first and second prestressing strands as the first structural elements, which are arranged crossing one another.