DE10129965A1 - Method and device for welding - Google Patents

Abstract

Process for welding parts, in particular those made of light metal alloys by means of a plasma, in which an arc is ignited between an essentially non-consumable electrode and the workpiece to be welded, both of which are connected to a power supply, and a plasma gas, e.g. , B. argon, helium or the like. Is blown. In order to be able to weld workpieces that are difficult to weld, especially those made of light metal alloys quickly and with high quality, it is provided that the power supply is designed as a direct current source and to the electrode (9) the positive pole thereof and to the workpiece (138) its negative pole are applied and the workpiece (13) is kept electrically insulated from electrical ground, the immediate vicinity of the end of the rod-shaped electrode (9) facing the workpiece (138) being kept at the potential of the workpiece (9).

Description

The invention relates to a method for welding according to the preamble of claim 1.

When welding light metal and light metal Alloys use a rod-shaped electrode. To one high welding speed with deep penetration and narrow To achieve seams, the rod-shaped electrode is used as the cathode switched and the workpiece electrically connected to ground, using helium as the plasma gas. This creates a very hot plasma that evaporates thin oxide layers. However, this is not the case with all light metal alloys Case.

In order to be able to weld such alloys, too in a method of the type mentioned at the beginning instead of with Direct current welded with alternating current, the workpiece is connected to electrical ground. This will make one permanent removal of the oxide layers ensured and a void-free welded connection allows because the oxide skin is constantly being torn open, but this advantage stands for Disadvantage of a welding speed reduced by approx. 2/3, compared to a direct current / helium weld and one significant increase in the width of the weld seams with increased Heat affected zone opposite.

The aim of the invention is to overcome these disadvantages avoid and a procedure of the type mentioned propose that a high welding speed even with allows difficult alloys and with that too it can be ensured that oxide layers formed be removed.

This is according to the invention in a method of type mentioned above by the characteristic features of the Claim 1 reached.

The proposed measures will ensures that even when difficult to weld Alloys, in particular light alloy forming Oxide layers are constantly torn open and therefore welds can be achieved with high quality. It is by the of electrical ground insulated holder of the workpiece and that Applying the potential of the workpiece to the environment of the Light ignition of workpiece towards end of electrode  of the arc and high stability of the emerging Focal spot ensures that the welds are narrow kept and the zone affected by the heat kept small can be. It can also be used in this way reach a relatively high welding speed.

Because of the easy ignitability it is also possible instead of with a substantially constant flow plasma with a Sequence of short plasma pulses to work like this through the Features of claim 2 is ensured. This will make the Wear of the electrode is significantly reduced.

Another object of the invention is to provide a Device for performing the method according to the invention propose.

To establish a facility according to the preamble of Claim 3 to be designed so that it for the implementation of the is suitable method, the characteristic features of claim 3 proposed.

The proposed action is simple Way ensured that the environment of the workpiece facing end of the electrode at the potential of the Workpiece lies, whereby the easy ignitability of the Arc between the electrode and the workpiece is ensured. In addition, the stability of the Focal spots on the workpiece due to the electrical from ground insulated holder of the workpiece very much increased and thereby improving the quality of the weld and at the same time the thermal load on the workpiece is reduced. At the same time, this also has a disruptive influence on electrical and electronic equipment in the area significantly reduced.

The features of claim 4 achieve that the end of the electrode facing the workpiece quickly a takes on essentially spherical form and also at a new electrode no essential, the weld negative influencing changes of the electrode geometry reveal how this z. B. the case with tapered electrode ends would.

By the features of claim 5 can be correspondingly short voltage pulses for simple Generate a pulse plasma.

The invention will now be described with reference to the drawing  erläutet. Show:

Fig. 1 shows a section through a plasma torch for an inventive device,

Fig. 2 shows a section along the line II-II in FIG. 1,

Fig. 3 is a section along the line III-III in FIG. 1,

Fig. 4 shows a section along the line IV-IV in Fig. 1,

Fig. 5 is a partial section through the plasma torch of FIG. 1,

Fig. 6 is a sleeve on which the helical channels are formed,

Fig. 7 schematically shows a circuit diagram of a power supply for a device according to the invention including connection of a workpiece to the power supply.

A device according to the invention has a base body 1 made of an electrically highly conductive material. This is covered at the top with a cover made of an electrically insulating material and fastened by means of the screws 3 . This base body 1 has a central bore 4 , which ends in the uppermost region of the base body and merges into a radial bore 5 , which ends in a connection 5 for a cooling water inlet.

In an extension of this central bore 4 , a sleeve 7 provided with a flange at its upper end is inserted. In the uppermost area of this sleeve 7 , it is pressed into a hollow holder 8 for an electrode 9 , which holder 8 is made of an electrically and thermally highly conductive material, such as, for. B. copper is made. This holder 8 is connected to the base body 1 by means of screws 10 inserted on the end face thereof and is in electrically good contact with the latter. In this case, a seal 11 is inserted in the base body 1 , which seals the holder 8 .

On the base body 1 is an annular intermediate piece 12 made of an electrically insulating material, which is provided with a radial bore 13 which ends on the outside of the intermediate piece 12 in a gas connection 14 .

An annular chamber 15 , through which the holder 8 passes, remains between the inner wall of the annular intermediate piece 12 and the holder 8 . The intermediate piece 12 bears against axial projections of the base body 1 and a support body 16 which essentially corresponds to it, wherein seals 17 , 18 are inserted in these projections.

The intermediate piece 12 is connected to the support body 16 and the base body 1 via screws 20 , 21 which engage in threaded bores of non-metallic inserts 28 and through which these screws 20 , 21 pass. The inserts 28 are embedded in the intermediate piece 12 made of insulating material and do not produce an electrically conductive connection between the base body 1 and the support body 16 .

The supporting body 16 has a central axial bore which is penetrated by the holder 8, wherein between the holder 8 and the inner wall of the supporting body 16 remains an annular gap 19, can flow through the gas to form a plasma from the chamber. 13

Furthermore, the support body 16 has a chamber 22 formed by a recess, into which a cooling water outlet 23 opens. In the chamber 22 of the support body 16 , an annular overflow body 24 is inserted, which protrudes at both ends into the annular gap 19 between the inner wall of the support body 16 and the holder 8 and is sealed in this annular gap 19 by means of seals 25 , 26 which are in grooves 26 'of the holder 8 are inserted ( Fig. 6).

The overcurrent body 24 has a plurality of axially continuous channels 27 and is provided with two radial bores 29 . The areas of these bores 29 are kept free from the channels 27 , so that gas can only flow through the overflow body 24 outside the areas of the projections of these bores 29 .

The holder 8 has radial bores 30 in the region of the radial bores 29 of the overflow body 24 , which produce a connection between the chamber 22 of the support body 16 and an annular gap 31 which extends between an expansion of the central bore 32 of the hollow holder 8 and the sleeve 7 remains. In the lower region of the holder 8 , an internal thread 33 is provided, into which a cap 34 holding the electrode is screwed, which is part of the holder 8 and overlaps the end of the sleeve 7 with play.

In addition to recesses 35 , which allow a tool to be used to tighten and loosen the cap 34 , this cap 34 has a conical outer surface which runs essentially parallel to the inner wall of a conical nozzle 36 .

Furthermore, the holder 8 is provided in the area immediately adjacent to its cap 34 with a thickening 37 , into which, as can be seen in particular from FIGS. 5 and 6, helical channels 38 are incorporated.

The cone nozzle 36 is integrally formed on a sleeve 39 which is screwed into the support body 16 and sealed with a seal 40 . The sleeve 39 is provided in the region of its cylindrical section on the inside with a coating 41 made of insulating material.

The base and the support body 1 , 16 are each provided with electrical insulation 42 .

The base body 1 and the holder 8 which is in an electrically conductive connection therewith and thus also the electrode 9 , which is usually made of a tungsten alloy, are via a cooling water connection, not shown, which can be inserted into the connection 6 and at the same time as an electrical connection to one Power source, not shown, can be connected to this. The second pole of the power source is connected to a workpiece, not shown.

In operation, cooling water flows through the connection 6 , flows through the bores 5 and 6 and subsequently the sleeve 7 and gets into the cap 34 of the holder 8 and is deflected in this and rises in the annular gap 19 between the sleeve 7 and the inner wall of the Holder 8 in the chamber 22 up. From there, the heated cooling water passes through the connection 23 to a cooling water discharge line, not shown.

The gas required to form a desired plasma is supplied via the gas connection 14 and passes through the bore 13 into the chamber 15 , through which the holder 8 passes. The gas flows downward from this chamber, flowing through the channels 27 of the overflow body 24 and reaching the region of the helically extending channels 38 which result between the thickening 37 and the coating 41 of the sleeve 39 .

When flowing through these channels, the flowing gas is given a corresponding swirl and it flows through this swirl through the cone nozzle 36 , which is determined by the conical section of the sleeve 39 and the cap 34 of the holder 8 .

From the mouth of this nozzle 36 , from which the electrode 9 protrudes, the gas flows, for. B. argon, helium or the like. At high speed and a corresponding swirl and forms a very stable gas column, which is ionized by a between the electrode, which is connected to the positive pole of the direct current source, and the workpiece burning arc and to the plasma becomes.

The gas column, which is very stable due to the swirl, keeps the focal spot on the workpiece connected as a cathode stable and prevents it from constantly migrating. The conical shape of the nozzle 36 also results in a significant constriction of the plasma column, as a result of which the focal spot is kept small and there is a high energy density in it.

A power supply for a plasma torch 100 according to FIGS. 1 to 6 is shown in FIG. 7, the power supply 200 being suitable for generating a pulse plasma as well as a flow plasma.

A capacitor battery 130 is connected to the terminals X1 of a controllable DC voltage source 132 via a charging resistor 131 . The capacitor bank 130 has a permanently connected capacitor 1 C1 and a capacitor 1 C2 which can be connected in parallel to this via a switch 1 S1, both of which can also be groups of capacitors.

This capacitor bank 130 is connected via connecting lines 133 , 134 to the plasma torch 100 , or its electrode 9 and the workpiece 138 ( not shown in FIG. 7), the positive pole being on the electrode 9 and the negative pole on the workpiece 138 .

An R / C element, which is formed by a capacitor 1 C3 and a resistor 1 R1, is connected in parallel with the capacitor bank 130 . In conjunction with the choke 1 L1 connected in the connecting line 133 , this R / C element forms an RF blocking circuit which is provided to protect the capacitor bank 130 and the power supply against RF signals.

Furthermore, an igniter 135 is connected to the connecting lines 133 , 134 , and these are also passed through the igniter 135 . This igniter 135 is connected on the input side to an AC voltage source X2 and is provided with a trigger switch 152 , by the actuation of which an ignition pulse can be triggered.

The connecting line 134 is connected to the workpiece 138 . The connecting line 133 is connected to the electrode 9 . The nozzle 36 is connected to the workpiece 36 via a high-resistance resistor 1 R2.

The resistor 36 of the plasma torch 100 is therefore at the potential of the workpiece 138 via the resistor 1 R2. This leads to the formation of an electric field between the nozzle 36 and the electrode 9 connected as an anode and thus to an ionization of the gap between these parts of the plasma torch 100 , which facilitates the ignition of an arc between the electrode 9 and the workpiece 138 . However, due to the high-impedance resistor 1 R2, there is no formation of an arc between the nozzle 36 and the electrode 9 , since an adequate current flow cannot form via this path.

The ionized plasma gas thereby forming a plasma by the inflowing plasma gas in the region between the electrode 9, which may consist of the workpiece 138 facing end face of the Plasmabren projecting ners 100 and the workpiece 138 pushed and be affects a rapid ignition of an arc, , The ignition is made considerably easier by the ionization of the air between the nozzle 36 and the electrode 9 .

If a pulse plasma is desired, ie only individual short plasma pulses should be generated in a more or less rapid sequence, e.g. B. for the production of a spot weld with very small distances between the individual welding spots, so only the capacitor bank is used. This leads to charging of the capacitor bank 130 in accordance with the set voltage of the DC voltage source 132 , which, for. B. is adjustable between 50 V and 300 V, and the time constant determined by the capacitance of the capacitor bank 130 and the line resistances and the charging resistor 131 .

When the capacitor bank 130 reaches a voltage which, taking into account the ionization of the area between the nozzle 36 and the workpiece 138 , into which area the ionized gas cloud which forms between the nozzle 36 and the electrode 9 is blown by the inflowing plasma gas, the breakdown voltage of the electrodes -Workpiece- corresponds to path 9 , 138 , then an arc is ignited and thus plasma is formed in the area between the electrode 9 and the workpiece 138 .

At the same time, the capacitor bank 130 discharges in accordance with the time constant given by its capacitance and the line resistances and the resistance of the arc. If, as a result of this discharge, the voltage of the capacitor bank 130 drops below the operating voltage of the arc, the arc extinguishes and the capacitor bank 130 recharges itself, as a result of which the process described is repeated and a frequency results which is determined by charging and discharging time constants , It is not necessary to operate the ignitor.

For certain applications, it may be desirable to determine the ignition timing of the arc precisely or to trigger it before the breakdown voltage of the electrode-workpiece path 9 , 138 is reached , in order to be able to generate particularly short plasma pulses.

In this case, an actuation pulse is triggered by actuation of the trigger switch 1 S2, which leads to rapid and extensive ionization of the area between the electrode 9 and the workpiece 138 and thus to the ignition of an arc without the capacitor battery 130 corresponding to the breakdown voltage of this distance Has reached tension. In this way, the duty cycle, the z. B. between 1:10 and 1: 100 and beyond can be changed accordingly and the ratio between the burning time of the arc and its pause during a cycle can be changed in terms of an extension of the pause, since the energy of the ignition pulses of the ignition device 135 is sufficient to ignite the arc, but not sufficient to maintain it when the voltage of the capacitor bank 130 has dropped below the operating voltage of the arc.

For applications in which a very large duty cycle or even a constant plasma, that is to say a flow plasma, is desired, the power supply also has a power supply unit 136 which is connected to an AC voltage network and is provided with a rectifier circuit.

The connected to the positive pole of the output of the power supply lead 133 'is connected to the positive pole of the capacitor bank 130 connected to lead 133 and the electrode 9 of the plasma torch 100 is connected and the connected to the negative pole of the power supply 136 lead 134' is connected to the connected to the negative pole of the capacitor bank 130 connecting line 134 , which is connected to the workpiece 138 and via the high-resistance resistor 1 R2 to the nozzle 36 of the plasma torch 100 .

Furthermore, a current monitor 137 is connected to the power supply 136 .

In operation, the power supply 136 also supplies current to the plasma torch 100 as soon as an arc is ignited in the manner described above, the circuit for the power supply 136 via the electrode 9 of the plasma torch, the plasma and the workpiece 138 , and the connecting lines 133 ', 133 , 134 ' is closed.

As soon as the arc in the plasma torch 100 goes out due to the drop in the voltage of the capacitor bank 130 below the arc voltage, the circuit for the power supply 136 is interrupted, the output voltage of which is not sufficient to maintain an arc between the electrode and the workpiece 138 receive.

By appropriate choice of the supply voltage of the capacitor bank 130 and the power supply, which is via a variable voltage source, for. B. a control transformer is supplied with a variety of voltage taps with AC voltage, a smooth transition from pulse plasma with an adjustable duty cycle and a constantly burning flow plasma is possible, in which only one arc has to be ignited for one operation, which by the power supply 136 is constantly supplied with sufficient energy so that it does not go out.

As can further be seen from FIG. 7, the workpiece 138 rests on a base 301 made of an electrically well-insulating material, which lies on an earthed carrier. The housing of the welding device 300 , which contains the entire power supply, is connected to ground.

The workpiece is therefore connected to the negative pole of the welding device 300 but not to electrical ground and the same electrical potential is present at the nozzle 36 of the plasma torch 100 as on the workpiece 138 .

Claims (5)

1. A method for welding parts, in particular those made of light metal alloys by means of a plasma, in which an arc is ignited between an essentially non-consumable electrode and the workpiece to be welded, both of which are connected to a power supply, and a plasma gas in this area , e.g. Is blown od as argon, helium, or the like., Characterized in that the power supply is constructed as a DC power source and the positive pole thereof and whose negative pole is applied to the electrode (9) to the workpiece (138) and the workpiece (138) against electrical ground is kept electrically isolated, the immediate environment is kept of the workpiece (138) facing end of the rod-shaped electrode (9) at the potential of the workpiece (138). 2. The method according to claim 1, characterized in that only voltage pulses are applied to the electrode ( 9 ) and the workpiece ( 138 ). 3. Device for performing the method according to claim 1 with a plasma torch ( 100 ) with a plasma gas flow-through nozzle ( 36 ), which is made of an electrically highly conductive material and concentric to an electrically insulated from the nozzle ( 36 ), rod-shaped , Non-consuming electrode ( 9 ) is arranged, which is connected to one pole of the direct current source, and a connection connected to the second pole of the direct current source for a workpiece ( 138 ) to be welded, an HF ignition device ( 135 ) having the rod-shaped electrode ( 9 ) and the workpiece ( 138 ) are connected, characterized in that the positive pole of the direct current source is connected to the rod-shaped electrode ( 9 ) aligned axially with the nozzle ( 36 ) and this is connected via a high-resistance resistor ( 1 R2) is connected to the workpiece ( 138 ) whose resistance value is in the range from 10 ³ to 10 ⁶ ohms, preferably 10 ⁵ ohms m, lies, the workpiece ( 138 ) being insulated from electrical ground. 4. Device according to claim 3 , characterized in that the electrode ( 9 ) connected to a positive pole protrudes with its free end from the nozzle ( 36 ) and is substantially blunt. 3. Device according to claim 3 or 4, characterized in that a capacitor battery ( 130 ) is provided for power supply, which is connected to a charging circuit ( 131 , 132 ) and on the output side with the electrode ( 9 ) of the plasma torch ( 100 ) and the workpiece ( 138 ), a power supply unit ( 136 ) which is preferably provided with a rectifier circuit and which is connected to the poles of the same name of the capacitor bank ( 130 ).