AT520866B1 - Resistance welding device and method for manufacturing wire netting - Google Patents

Abstract

The invention relates to a resistance welding device for producing wire mesh with longitudinal rods which can be inserted parallel to a longitudinal direction of the resistance welding device and transverse rods which can be inserted at an angle thereto in the transverse direction of the resistance welding device, the resistance welding device comprising: a first welding head with a first welding electrode; a second welding head with a second welding electrode, wherein a contact electrode is formed on the first welding head and a current bridge is formed on the second welding head, which is electrically conductively coupled to the second welding electrode, wherein the contact electrode can be brought into direct contact with the current bridge and wherein the to longitudinal bar and transverse bar to be welded can be clamped simultaneously between the first welding electrode and the second welding electrode, characterized in that a transformer is arranged on the first welding head and is electrically conductively coupled to the first welding electrode and to the contact electrode.

Description

description

The invention relates to a resistance welding device for producing wire meshes with longitudinal bars and transverse bars, and a method for producing wire meshes with longitudinal bars and transverse bars.

DE1107855B discloses a mesh welding machine with a first and a second welding head. A current bridge is arranged on the first welding head. A first and a second welding electrode are arranged on the second welding head, a first longitudinal bar and a transverse bar being able to be inserted between the first welding electrode and the current bridge and a second longitudinal bar and the transverse bar being able to be inserted between the second welding electrode and the current bridge. The first longitudinal bar and the second longitudinal bar are simultaneously welded to the transverse bar.

From AT292427B a mesh welding machine is known which has a first welding electrode which is arranged on a first welding head and has a second welding electrode which is arranged on a second welding head, with a longitudinal rod and between the first welding electrode and the second welding electrode a crossbar can be introduced to weld them together. The first welding head is electrically coupled to a first busbar by means of pickups. The second welding head is electrically coupled to a second busbar by means of pickups.

Other mesh welding machines are known from EP0335858A2, WO02070168A1, AT 365492 B and AT 295294 B.

The mesh welding machine known from DE1107855B has the disadvantage that the amount of current on the first and on the second longitudinal bar cannot be regulated independently of one another. It is therefore not possible to ensure reliable welding of both longitudinal bars. In addition, it is not possible to weld two longitudinal bars with different thicknesses to the transverse bar, as this would result in different welding depths.

The known from AT292427B mesh welding machine has the disadvantage that the first welding head can only be moved in the transverse direction when no longitudinal rod is used in the mesh welding machine.

The object of the present invention was to overcome the disadvantages of the prior art and to provide a device and a method by means of which wire meshes with longitudinal bars and transverse bars can be produced flexibly.

[0008] This object is achieved by a device and a method according to the claims.

According to the invention, a resistance welding device is designed for producing wire meshes with longitudinal rods, which can be inserted parallel to a longitudinal direction of the resistance welding device, and transverse rods, which can be inserted parallel to a transverse direction of the resistance welding device aligned at right angles to the longitudinal direction. The resistance welding device includes:

a first welding head having a first welding electrode;

a second welding head with a second welding electrode.

A contact electrode is formed on the first welding head and a current bridge is formed on the second welding head, which is electrically conductively coupled to the second welding electrode, the contact electrode being able to be brought into direct contact with the current bridge and the longitudinal rods and transverse rods to be welded simultaneously between the first welding electrode and the second welding electrode can be clamped.

The resistance welding device according to the invention has the advantage that the longitudinal rod and the transverse rod are only clamped between the first welding electrode and the second welding electrode and thus the energy input for welding the longitudinal rod

bes and the crossbar can be precisely determined. In this case, the contact electrode is coupled in a current-carrying manner to the current bridge, so that a current supply or current discharge must be arranged exclusively on the first welding head and only the second current bridge can be arranged on the second welding head.

Furthermore, it can be useful if a transformer is arranged on the first welding head, which is electrically conductively coupled to the first welding electrode and to the contact electrode. The advantage here is that the energy required for the welding process does not have to be supplied by a busbar from a transformer that is far away from the contact electrodes, but that the lines, which are arranged between the transformer and the welding electrode and therefore have to carry a high current intensity, can be kept as short as possible. As a result, the energy loss at the resistance welding device can be kept as low as possible.

Furthermore, it can be provided that the first welding head is coupled to a first linear guide and can be displaced along it, and that the second welding head is coupled to a second linear guide and can be displaced along it. The two linear guides are aligned in the transverse direction of the resistance welding device, so that the two welding heads can be displaced in the transverse direction of the resistance welding device. This measure makes it possible for wire meshes of different configurations to be welded to one another. In particular, this can increase the flexibility of the resistance welding device.

In addition, it can be provided that at least two first welding heads are arranged on the first linear guide and at least two second welding heads are arranged on the second linear guide. The advantage here is that the individual pairs of welding heads can be operated in parallel with one another and thus the production speed of the resistance welding device can be increased.

Also advantageous is an embodiment according to which it can be provided that the current bridge has a contact element which is conical and that the contact electrode is correspondingly hollow conical. This measure allows the contact surface between the contact element and the contact electrode to be increased, so that the current transmission between the contact element and the contact electrode can be improved.

According to a further development, it is possible for the first welding electrode to be coupled to a first actuator, in particular to a pneumatic cylinder, and to be displaceable in the direction of the second welding electrode. This measure allows the longitudinal bars and transverse bars to be clamped between the first welding electrode and the second welding electrode.

It can also be useful if the contact electrode is coupled to a second actuator, in particular to a pneumatic cylinder, and can be displaced in the direction of the current bridge. This measure allows the contact electrode to be lifted off the current bridge, so that the welding heads can be displaced in the transverse direction of the resistance welding device over existing longitudinal rods.

In addition, it can be provided that the first actuator and the second actuator can be actuated independently of one another. This measure makes it possible for the contact electrode to be brought into contact with the current bridge independently of the welding electrode, in order to enable current to flow.

Furthermore, it can be provided that a first flexible current bridge is formed, by means of which the first welding electrode is coupled to the transformer. This measure allows the welding electrode to be shifted relative to the transformer.

[0019] According to a particular embodiment, it is possible for a second flexible current bridge to be formed, by means of which the contact electrode is coupled to the transformer.

This measure allows the contact electrode to be shifted relative to the transformer.

According to an advantageous development it can be provided that the current bridge is coupled to an adjustment device, by means of which it can be displaced in the direction of the first welding electrode. This measure allows the current bridge to be adapted to differently designed wire meshes.

In particular, it can be advantageous if the adjusting device comprises an eccentric which is coupled to a drive unit, in particular a servomotor.

Furthermore, it can be provided that the current bridge has a cooling channel in which a cooling medium can be guided. The current bridge can be cooled by this measure, as a result of which the current-conducting properties of the current bridge are improved.

In addition, it can be provided that the first welding electrode and the contact electrode of the first welding head are offset from one another in the transverse direction of the resistance welding device. It can thereby be achieved that the contact electrode can be passed through between the individual longitudinal bars and transverse bars and can thus be brought into direct contact with the current bridge.

According to the invention, a method for producing wire netting with longitudinal bars and transverse bars is also provided. The procedure comprises the following procedural steps:

- positioning of a transverse bar relative to a longitudinal bar;

-_ Positioning a first welding head and a second welding head in such a way that an overlapping area of the transverse rod and the longitudinal rod is arranged between a first welding electrode of the first welding head and a second welding electrode of the second welding head and that the contact electrode can be brought into direct contact with the power bridge, without touching a longitudinal bar or a transversal bar;

- Moving the contact electrode to the current bridge until the contact electrode is brought into contact with the current bridge;

- moving the first welding electrode to the second welding electrode so that the longitudinal bar and the transverse bar are clamped between the first welding electrode and the second welding electrode;

- applying current to the welding electrodes so that the transverse bar and the longitudinal bar are welded together;

- distance the two welding electrodes from each other and the contact electrode from the current bridge.

The advantage of the method according to the invention is that wire meshes with increased flexibility can be produced by this method.

The term wire mesh is used for all structures that have a lattice structure with longitudinal bars and transverse bars. The longitudinal bars and transverse bars can be arranged at any angle to one another and have any shape.

In a first exemplary embodiment, the wire mesh can be designed, for example, as a reinforcement mat, which serves as reinforcement in concrete structures.

In a further embodiment, the wire mesh can be designed as a grid. In a further embodiment, the wire mesh can be designed as a grating.

For a better understanding of the invention, it will be explained in more detail with reference to the following figures.

[0031] In each case, in a highly simplified, schematic representation:

1 is a perspective view of an embodiment of a resistance welding device;

Figure 2 is a perspective view of an embodiment of a first and second weld head;

3 is another perspective view of an embodiment of the first and second welding heads.

First of all, it should be noted that in the differently described embodiments, the same parts are provided with the same reference numbers or the same component designations, with the disclosures contained throughout the description being able to be transferred analogously to the same parts with the same reference numbers or the same component designations. The position information selected in the description, such as top, bottom, side, etc., is related to the figure directly described and shown and these position information are to be transferred to the new position in the event of a change of position.

1 shows a schematic representation of a resistance welding device 1 for producing wire meshes 2 with longitudinal bars 3 and transverse bars 4.

The longitudinal rods 3 are guided in the resistance welding device 1 in such a way that they run parallel to a longitudinal direction 5 of the resistance welding device 1 . The transverse rods 4 are guided in the resistance welding device 1 in such a way that they run parallel to a transverse direction 6 of the resistance welding device 1 .

In particular, it can be provided that the longitudinal bars 3 and the transverse bars 4 of the wire mesh 2 are arranged at right angles to one another.

In a preferred embodiment of the present embodiment, the wire mesh 2 is designed as a reinforcement mat. The longitudinal rods 3 and transverse rods 4 are accordingly designed as round material made from reinforcing steel. The longitudinal bars 3 and the transverse bars 4 can have different diameters. Furthermore, it is also conceivable that, for example, two adjacent longitudinal bars 3 or two adjacent transverse bars 4 have a different diameter. In a preferred embodiment, it is provided that the transverse bars 4 are all arranged on one side of the longitudinal bars 3 and are welded to the longitudinal bars 3 by means of the resistance welding device 1 .

The resistance welding device 1 has at least a first welding head 7 with a first welding electrode 8 and a second welding head 9 with a second welding electrode 10.

As can be seen from FIG. 1, it can be provided that the resistance welding device 1 has a plurality of first welding heads 7 or a plurality of second welding heads 9 . The first welding heads 7 are arranged on a first linear guide 11, by means of which the welding heads 7 can be displaced in the transverse direction 6 of the resistance welding device 1. Analogously to this, the second welding heads 9 can be displaceable in the transverse direction 6 of the resistance welding device 1 by means of the second linear guide 12 .

In particular, it can be provided that the first linear guide 11 has a first guide rail 13 which is arranged on the base frame 14 . Each of the first welding heads 7 can be coupled to a first guide carriage 15 which interacts with the first guide rail 13 . In particular, provision is made here for the first guide carriages 15 to be accommodated in the first guide rail 13 in a displaceable manner.

[0043] Analogously to this, it can be provided that the second linear guide 12 comprises a second guide rail 16 which is also accommodated on the base frame 14 .

It is also provided that each of the first welding heads 7 and each of the second welding heads 9 is coupled to a drive unit so that the welding heads 7, 9 can be displaced or positioned in the transverse direction 6 of the resistance welding device 1. In the present exemplary embodiment, it is provided that each of the welding heads 7, 9 has its own drive unit and the welding heads 7, 9 are thus displaced or positioned independently of one another in the transverse direction 6 of the resistance welding device 1

be able. In another exemplary embodiment, it can also be provided that a first welding head 7 and an associated second welding head 9 are coupled to a common drive unit and can therefore always be adjusted in pairs relative to one another.

The drive unit for adjusting the welding heads 7, 9 can, for example, comprise an electric motor which is arranged on the base frame 14 and is coupled to a drive roller which drives a toothed belt running between the drive roller and a deflection roller. The toothed belt is coupled to the welding head 7, 9 in this case.

In a further exemplary embodiment it can also be provided that the drive unit is arranged directly on the welding heads 7, 9 and is coupled to a gear which engages in a rack arranged on the base frame 14.

Of course, all other drive units known to those skilled in the art can also be used for positioning the welding heads 7, 9.

In the figures 2 and 3 a further and possibly independent embodiment of the welding heads 7, 9 is shown, again for the same parts the same reference numerals or component designations are used as in the previous Fig. 1. In order to avoid unnecessary repetitions, reference is made to the detailed description in the preceding FIG. 1 .

In particular, FIGS. 2 and 3 show an exemplary embodiment of the first welding head 7 and the associated second welding head 9 in various perspective views, with the further description of the welding heads 7, 9 being based on a synopsis of FIGS.

As can be seen from FIGS. 2 and 3, it is provided that the first welding head 7 has a contact electrode 18 next to the first welding electrode 8 . The contact electrode 18 can be brought into contact directly with a current bridge 19 which is arranged on the second welding head 9 . In particular, it can be provided that a contact element 20 is arranged on the current bridge 19, with which the contact electrode 18 can be contacted. As can be seen from FIGS. 2 and 3, provision can be made for the second welding electrode 10 and the contact element 20 to be arranged directly on the current bridge 19 . As can be seen from FIGS. 2 and 3, it can be provided that the first welding head 7 and the second welding head 9 are positioned relative to one another in such a way that the first welding electrode 8 and the second welding electrode 10 are arranged opposite one another and the contact electrode 18 and the contact element 20 are arranged opposite one another.

It is further provided that the first welding electrode 8 is coupled to a first actuator 21 and that the contact electrode 18 is coupled to a second actuator 22. In particular, it can be provided that the first actuator 21 and the second actuator 22 as a hydraulic or Pneumatic cylinders are formed. In this case, the first welding electrode 8 can be arranged on a piston rod of the first actuator 21 and the contact electrode 18 can be arranged directly on a piston rod of the second actuator 22 . In the present exemplary embodiment it is provided that the first actuator 21 and the second actuator 22 can move the first welding electrode 8 or the contact electrode 18 in an infeed direction 23 independently of one another. By shifting the contact electrode 18 in the infeed direction 23, it can be brought together with the contact element 20. By moving the first welding electrode 8, it can be brought together with the second welding electrode 10.

Provision can also be made for a transformer 24 to be arranged on the first welding head 7, by means of which the welding current required for resistance welding is provided. It can thus be provided that each of the first welding heads 7 has its own transformer 24 which is arranged directly on the welding head 7 and can be displaced with the welding head 7 in the transverse direction 6 of the resistance welding device 1 .

It is also provided that the first welding electrode 8 is coupled to the transformer 24 by means of a first flexible current bridge 25 . By this measure, the first

Welding electrode 8 are shifted relative to the transformer 24 in the delivery direction 23.

It is also provided that the contact electrode 18 is coupled to the transformer 24 by means of a second flexible current bridge 26 . This measure allows the contact electrode 18 to be displaced in the infeed direction 23 relative to the transformer 24 . The first welding electrode 8 and the contact electrode 18 are electrically conductively coupled to the transformer 24 by means of the first flexible current link 25 and the second flexible current link 26 . In particular, it is provided that the flexible current bridges 25, 26 have a large conductor cross-section in order to be able to transmit the high currents required for resistance welding. The flexible current bridges 25, 26 can in this case have a structure composed of a plurality of individual small plates or foils, through which the current bridges 25, 26 are designed to be flexible. In particular, it can be provided that the flexible current bridges 25, 26 are formed from a copper material.

Provision can also be made for the current bridge 19 of the second welding head 9 to be coupled to an adjustment device 27, by means of which the current bridge 19 is arranged on the second welding head 9 so that it can be displaced in the infeed direction 23. The adjustment device 27 can include an eccentric 28 which is coupled to a drive unit 29 which is used to rotate the eccentric 28 . The displacement in the infeed direction 23 can be achieved by the twisting movement of the eccentric 28 by means of the drive unit 29 . The drive unit 29 can preferably be designed in the form of an electric motor, in particular a servo motor. A servomotor has the advantage that an exact delivery of the current bridge 19 is made possible or that the position of the current bridge 19 can be determined exactly.

Furthermore, it can be provided that the current bridge 19 of the second welding head 9 is arranged on the second welding head 9 in an electrically insulated manner, so that it has no conductive connection to another component of the second welding head 9 .

Provision can furthermore be made for the current bridge 19 to have a cooling channel 30 which is used to conduct a cooling medium, as a result of which the current bridge 19 can be cooled. Coolant connections 31 can be connected to the cooling duct 30 , by means of which the cooling medium can be introduced into the cooling duct 30 . A fluid such as a liquid, a gas or an aerosol can be used as the cooling medium.

Of course, a cooling channel can also be formed in the area of the first welding electrode 8 and the contact electrode 18 . This cooling channel can also be formed in the power supply lines to the first welding electrode 8 and the contact electrode 18 .

Furthermore, it can also be provided that a cooling channel is formed in the transformer 24 .

As can also be seen from FIGS. 2 and 3, the first welding electrode 8 and the contact electrode 18 are spaced apart from one another by a distance 32 in the transverse direction and by a distance 33 in the longitudinal direction. Correspondingly, the second welding electrode 10 and the contact element 20 are spaced apart from one another by a distance 32 in the transverse direction and by a distance 33 in the longitudinal direction. By this measure it can be achieved that an overlap 34 of the longitudinal bar 3 and the transverse bar 4 can be placed between the first welding electrode 8 and the second welding electrode 10 and at the same time neither a longitudinal bar 3 nor a transverse bar 4 is arranged between the contact electrode 18 and the contact element 20 are. The distance 32 in the transverse direction and the distance 33 in the longitudinal direction are between 10 mm and 250 mm, in particular between 20 mm and 70 mm.

The process sequence for producing a resistance welded connection between a longitudinal bar 3 and a transverse bar 4 is described with reference to FIGS. 2 and 3 together.

In a first method step, the complete wire mesh 2 is positioned in the resistance welding device 1 in such a way that the crossbar 4 to be welded is at the same height as the first welding electrode 8 and the second welding electrode 10 . Contemporaneous

or in a preceding or subsequent method step, the first welding head 7 and the second welding head 9 are shifted in the transverse direction 6, so that the overlap 34 of the longitudinal bar 3 and the transverse bar 4 is arranged exactly between the first welding electrode 8 and the second welding electrode 10. This positioning situation is shown in FIG.

In a subsequent method step, the contact electrode 18 is moved by the second actuator 22 in the infeed direction 23 to the contact element 20 until the contact electrode 18 and the contact element 20 touch one another. As a result, a current-conducting connection between the contact electrode 18 and the contact element 20 can be established. Subsequently or at the same time, the first welding electrode 8 can be moved in the infeed direction 23 to the second welding electrode 10 until the longitudinal bars 3 and transverse bars 4 to be welded are clamped between the first welding electrode 8 and the second welding electrode 10 . Here, the longitudinal bar 3 can rest on the first welding electrode 8 and the transverse bar 4 on the second welding electrode 10 . Of course, it can also be provided that the transverse rod 4 rests on the first welding electrode 8 and the longitudinal rod 3 on the second welding electrode 10 .

To weld the transverse bar 4 to the longitudinal bar 3, the first welding electrode 8 is pressed with a predetermined pressure in the direction of the second welding electrode 10, so that the longitudinal bar 3 and the transverse bar 4 are pressed against one another with a predefined pressure. By introducing a predetermined amount of current into the first welding electrode 8 or into the contact electrode 18, the longitudinal bar 3 and the transverse bar 4 are heated due to their electrical resistance. The contact electrode 18 establishes a direct electrical line with the second welding electrode 10, so that a closed circuit can be formed starting from the transformer 24, with only the first welding electrode 8 and the second welding electrode 10 being spaced apart and the components to be welded between the first Welding electrode 8 and the second welding electrode 10 are arranged. The resistance welding device 1 can thus be operated as efficiently and energy-efficiently as possible.

After staying in this state for a predetermined welding time, the welding current is switched off again and the first welding electrode 8 and the contact electrode 18 are removed from the current bridge 19. The two welding heads 7, 9 can then be repositioned in the transverse direction 6 and/or in the longitudinal direction 5, so that an additional longitudinal bar and an additional transverse bar 4 or the same longitudinal bar 3 with an additional transverse bar 4 or the same transverse bar 4 with an additional longitudinal bar 3 can be welded.

Finally, for the sake of order, it should be pointed out that, in order to better understand the structure, some elements are shown not to scale and/or enlarged and/or reduced.

REFERENCE LIST

1 resistance welding device 30 cooling channel

2 wire mesh 31 coolant connection

3 Longitudinal bar 32 Transverse spacing 4 Transverse bar 33 Longitudinal spacing 5 Longitudinal 34 Overlap

6 transverse direction

7 first welding head

8 first welding electrode

9 second welding head

10 second welding electrode 11 first linear guide

12 second linear guide

13 first guide rail 14 base frame

15 first guide carriage 16 second guide rail 17 second guide carriage 18 contact electrode

19 power bridge

20 contact element

21 first actor

22 second actor

23 infeed direction

24 transformer

25 first flexible power bridge 26 second flexible power bridge 27 adjustment device

28 eccentric

29 drive unit

Claims (14)

patent claims 1. Resistance welding device (1) for producing wire mesh (2) with longitudinal rods (3) which can be inserted parallel to a longitudinal direction (5) of the resistance welding device (1) and transverse rods (4) which are positioned at an angle thereto in the transverse direction (6) of the Resistance welding device (1) can be inserted, the resistance welding device (1) comprising: a first welding head (7) with a first welding electrode (8); a second welding head (9) with a second welding electrode (10), a contact electrode (18) being formed on the first welding head (7) and a current bridge (19) being formed on the second welding head (9) which is electrically conductive with the second welding electrode (10), wherein the contact electrode (18) can be brought into direct contact with the current bridge (19) and wherein the longitudinal bar (3) and transverse bar (4) to be welded are simultaneously connected between the first welding electrode (8) and the second welding electrode ( 10) can be clamped, characterized in that a transformer (24) is arranged on the first welding head (7) and is electrically conductively coupled to the first welding electrode (8) and to the contact electrode (18). 2. Resistance welding device according to claim 1, characterized in that the first welding head (7) is coupled to and displaceable along a first linear guide (11) and that the second welding head (9) is coupled to and along a second linear guide (12). this can be moved. 3. Resistance welding device according to claim 2, characterized in that at least two first welding heads (7) are arranged on the first linear guide (11) and at least two second welding heads (7) are arranged on the second linear guide (12). 4. Resistance welding device according to one of the preceding claims, characterized in that the current bridge (19) has a contact element (20) which is conical and in that the contact electrode (18) is correspondingly hollow conical. 5. Resistance welding device according to one of the preceding claims, characterized in that the first welding electrode (8) is coupled to a first actuator (21), in particular to a pneumatic cylinder, and is displaceable in the direction of the second welding electrode (10). 6. Resistance welding device according to one of the preceding claims, characterized in that the contact electrode (18) is coupled to a second actuator (22), in particular to a pneumatic cylinder, and is displaceable in the direction of the current bridge (19). 7. Resistance welding device according to claim 6, characterized in that the first actuator (21) and the second actuator (22) can be actuated independently of one another. 8. Resistance welding device according to one of claims 1 to 7, characterized in that a first flexible current bridge (25) is formed, by means of which the first welding electrode (8) is coupled to the transformer (24). 9. Resistance welding device according to one of claims 1 to 8, characterized in that a second flexible current bridge (26) is formed, by means of which the contact electrode (18) is coupled to the transformer (24). 10. Resistance welding device according to one of the preceding claims, characterized in that the current bridge (19) is coupled to an adjusting device (27) by means of which it can be displaced in the direction of the first welding electrode (8). 11. Resistance welding device according to claim 10, characterized in that the adjusting device (27) comprises an eccentric (28) which is coupled to a drive unit (29), in particular a servo motor. 12. Resistance welding device according to one of the preceding claims, characterized in that the current bridge (19) has a cooling channel (30) in which a cooling medium can be guided. 13. Resistance welding device according to one of Claims 2 to 12, characterized in that the first welding electrode (8) and the contact electrode (18) of the first welding head (7) are offset from one another in the transverse direction (6) of the resistance welding device (1). 14. Method for producing wire meshes (2) with longitudinal bars (3) and transverse bars (4), in particular using a resistance welding device (1) according to one of the preceding claims, the method comprising the following method steps: - Positioning of a transverse bar (4) relative to a longitudinal bar (3); - Positioning a first welding head (7) and a second welding head (9), with an overlapping area of the transverse bar (4) and the longitudinal bar (3) between a first welding electrode (8) of the first welding head (7) and a second welding electrode (10) of the second welding head (9) and that the contact electrode (18) is brought into direct contact with the current bridge (19) without touching a longitudinal rod (3) or a transverse rod (4); - Moving the contact electrode (18) to the current bridge (19) until the contact electrode (18) is brought into contact with the current bridge (19); - Moving the first welding electrode (8) to the second welding electrode (10) so that the longitudinal rod (3) and the transverse rod (4) are clamped between the first welding electrode (8) and the second welding electrode (10); - Applying current to the welding electrodes (8, 10) so that the crossbar (4) and the longitudinal rod (3) are welded together; - Distancing the two welding electrodes (8, 10) from each other and the contact electrode (18) from the current bridge (19), characterized in that the current is applied by means of a transformer (24) which is installed at the first welding Head (7) is arranged, wherein the transformer (24) electrically conductive with the first Welding electrode (8) and is coupled to the contact electrode (18). 3 sheets of drawings