DE19831831A1 - Shielding gas for TIG direct current welding of aluminum - Google Patents

Abstract

The invention relates to a protective gas and a method for TIG direct current welding of aluminum materials and aluminum alloys, the protective gas being fed to the welding point and the protective gas essentially containing helium or a mixture of helium and argon. DOLLAR A According to the invention, good welding results are achieved with a protective gas which either contains no argon in addition to helium and at least a portion of 275 vpm to 475 vpm nitrogen or in addition to helium and argon contains at least a portion of 275 vpm to 500 vpm nitrogen. DOLLAR A In one embodiment of the invention, the protective gas contains between 300 vpm and 450 vpm nitrogen. The protective gas preferably has at least 45% by volume of helium. 0.01 to 1% by volume of oxygen, carbon dioxide or a mixture of oxygen and carbon dioxide can be mixed into the protective gas as active components.

Description

The invention relates to a protective gas for TIG direct current welding of aluminum, Aluminum materials and / or aluminum alloys comprising helium or a Mixture of helium and argon. The invention also relates to a method for TIG direct current welding of aluminum, aluminum materials and / or Aluminum alloys, a protective gas being supplied to the welding point and the protective gas containing helium or a mixture of helium and argon.

The abbreviation TIG is used in specialist circles for the tungsten inert gas welding process used. These usually include welding processes with non-melting igniting or non-burning electrode using an inert gas the. The non-melting electrode (permanent electrode) generally consists of Tungsten. In connection with the present invention, a TIG Welding process any welding process with non-melting electrode ver stood. Usually the arc burns freely between the electrode and the workpiece.

Aluminum is becoming increasingly popular as a construction material over steel. This is due in large part to the weight saving that a use aluminum instead of steel materials.

There are some process variants of TIG welding with direct current among the known protective gas mixtures known. The peculiarity of welding Aluminum results from the property of aluminum, on the surface immediately to form an oxide layer. The formation of a firmly adhering oxide on the surface is the result of the base character of aluminum. The welding shield gas has the on sage, the distance of the electric arc between the electrode and the workpiece electrically conductive and both the weld pool and the melting to protect against the atmosphere and an unwanted To prevent oxidation. Argon is the most used shielding gas. Argon-helium gas mixtures can be advantageous despite the higher gas costs  be. This is due to the helium component, the better penetration and higher Allows welding speeds. It can also help reduce helium or contribute to the prevention of pores and the consumption of welding consumables reduce material. These advantages of helium compared to argon can be explained due to the hotter arc and the more favorable energy distribution in the arc.

More recently, doped protective gas mixtures with admixtures of others Components known in the vpm area.

DE 27 48 417 C2 describes a method for reducing ge during welding formed harmful ozone by adding 25 to 50 vpm nitrogen oxide the argon used as protective gas in TIG welding, but also in MIG and MAG welding known.

From DE 40 28 074 C1 and the corresponding EP 0 475 030 B1 it is known an inert protective gas from argon or from an argon-helium mixture with a Admixture of 80 to 250 vpm, preferably 120 to 180 vpm with an optimum at 150 vpm nitrogen, for TIG, MIG and MAG welding of aluminum put. With TIG AC welding, this serves to form a quiet, stable burning and concentrated arc and increased energy input supply. Above 250 vpm nitrogen there are annoying side effects such as seam distortion exercises (TIG welding) and sagging of the fillet welds (MIG welding).

Protection is provided in DE 41 06 900 A1 and the corresponding EP 0 502 318 B1 gas mixture of argon or one or more components from the group Helium, hydrogen, oxygen and carbon dioxide with an admixture of 80 to 250 vpm nitrogen, preferably 120 to 180 vpm nitrogen, known, which at TIG, MIG, MAG and plasma welding of steel materials, copper, nickel and Aluminum can be used. The shielding gas leads to an intensive penetration tion without deterioration of the predicament behavior.

From DE 42 41 982 C1 or the corresponding EP 0 673 295 B1 it is known to use a protective gas made of argon or an argon-helium mixture with an admixture of 80 to 250 vpm nitrous oxide (laughing gas), preferably 120 to 180 vpm Use nitrous oxide (with an optimum around 150 vpm N ₂ O) for TIG and MIG welding of aluminum. In TIG AC welding, the shielding gas is intended to produce a calm, stable, burning and concentrated arc and to increase the energy input. Above 250 vpm nitrous oxide there are troublesome side effects such as seam discoloration (TIG welding) and a strong sagging of the fillet welds (MIG welding).

DE 42 41 983 C1 and the corresponding EP 0 673 296 B1 describe an inert protective gas made from argon or from an argon-helium mixture with an admixture of 80 to 250 vpm N ₂ / N ₂ O, preferably 120 to 180 vpm with an optimum at 150 vpm N ₂ / N ₂ O, for TIG, MIG and MAG welding of aluminum. The proportions of N ₂ and N ₂ O in the protective gas can be in any ratio. With TIG AC welding, this serves to form a calm, stable burning and concentrated arc and an increased energy input. Above 250 vpm N ₂ / N ₂ O there are troublesome side effects such as seam discoloration (TIG welding) and sagging of the fillet welds (MIG welding).

From EP-0 761 380 A1 or the corresponding US-A-5 667 703 is a Process for TIG AC welding of aluminum and aluminum alloy stations known, in which the weld from a ternary shielding gas mixture at least 50 vol .-% helium, over 300 vpm nitrogen and argon as the balance (preferred at least 60 vol% helium, between 300 and 1000 vpm nitrogen and the rest Argon) is supplied. Based on the fact that helium in the protective gas on the one hand, switching the polarity of the tungsten electrode from emission to Reception due to its low promotion of gas ionization compared to argon difficult, but on the other hand the effectiveness of TIG welding of aluminum under alternating current, especially the penetration depth during welding and The compactness of the welding bead is said to be increased by this Shielding gas mixture the positive effect of helium can be exploited without arc stability or welding rate is noticeably affected.

In the German utility model DE 296 23 194 U1 there is a protective gas for light arc welding (TIG AC welding, MIG welding and powder plasma welding) of steel and non-ferrous materials such as aluminum, which from argon or an argon-helium-nitrogen and optionally hydrogen Mixture with an admixture between 50 and 450 vpm nitrogen monoxide (before  preferably 280 to 320 vpm NO). A specified set This protective gas mixture comprises 150 vpm nitrogen, 300 vpm nitrogen mon oxide, 10 vol.% helium and argon as the rest. The protective gas should be used when changing TIG current welding a stable, quiet arc with higher energy input and with lower noise emissions, better wetting on the seam flanks good penetration profile and a weld seam with a very fine-scaled appearance Act.

DE 40 07 673 C2 describes a method for TIG direct current welding of Aluminum with a negatively polarized electrode with a free-hand torch guidance with a Protective gas from at least 85 vol .-% helium and a residual amount of argon be knows.

The present invention has for its object a protective gas and supplied to show proper welding processes which lead to good welding results. Good welding properties should be guaranteed. At the TIG match Current welding with a negatively polarized electrode has no cleaning effect Surface by the electric current. Therefore this particular post should can be reduced as much as possible compared to TIG AC welding. Further If possible, a stable and calm arc with a high energy input should be used good penetration profile, high energy input, good quality of sweat seam can be achieved in particular without pores at high welding speed.

This object is achieved in that the protective gas either besides helium, no argon and at least a proportion of 275 vpm to 475 vpm stick material or in addition to helium and argon at least a proportion of 275 vpm to 500 vpm Contains nitrogen.

Surprisingly, it has been shown that a protective gas that either in addition to helium, no argon (apart from impurities) and at least a proportion of 275 vpm to 475 vpm (i.e., between 0.0275 and 0.0475 vol%) nitrogen or in addition Helium and argon at least a proportion of 275 vpm to 500 vpm (i.e. between 0.0275 and 0.05 vol .-%) contains nitrogen in TIG direct current welding excellent welding results. In particular, with stable and quiet arc at high welding speed an improved penetration  be achieved. It was also possible to reduce the welding current. At the Welding methods according to the invention can damage the electrode tip be prevented. The welds exhibit an extremely low level of Number of pores. Even thick-walled components can be welded without Cracks form.

The invention can basically be used in all TIG welding processes DC are used. This applies in particular to TIG direct current welding and TIG pulse welding (i.e. variation of the current profile during TIG direct current welding) with a negative polarity electrode, the additional work can be supplied as cold or hot wire.

In an embodiment of the invention, the protective gas contains between 300 vpm and 450 vpm, preferably between 325 and 425 vpm nitrogen.

The protective gas can advantageously be at least 45% by volume of helium, preferably at least Contain 60 vol .-% helium, particularly preferably 80 to 95 vol .-% helium.

In the embodiment of the invention, the protective gas can be 1 to 40% by volume argon, preferably Contain 10 to 35 vol .-% argon.

Active components, in particular oxygen, can also be used as protective gas and / or carbon dioxide. This can additionally improve the welding quality increase. In particular, a higher cleaning effect and / or a ver better (deeper and / or wider) penetration can be achieved. For this, the protective gas advantageously 0.01 to 1% by volume, preferably 0.01 to 0.2% by volume, particularly preferably 0.01 to 0.1 vol .-% oxygen, carbon dioxide or a mixture of Contain oxygen and carbon dioxide, the protective gas in addition to helium and ge optionally argon contains a proportion of 275 vpm to 500 vpm nitrogen. Also in Case that the protective gas containing active components except for impurities contains no argon, the nitrogen content in the protective gas can be between 275 vpm and 500 vpm. Excellent results were, for example, at 500 vpm Oxygen, with 500 vpm carbon dioxide and with an admixture of 300 vpm acid material and 200 vpm carbon dioxide. Especially the addition of oxygen works positive on the welding result and the quality.  

The protective gas according to the invention can ge, for example, at the user site be mixed (mixing with several stages is also possible) or as ready can be delivered mixed.

In principle, any suitable power source can be used in the method according to the invention Find use. In particular, thyristor-controlled or preferred transistorized current sources are used.

The surface can be brushed before welding. Through this In particular, a smooth seam surface can be achieved.

The invention is suitable for welding in all positions, including for that Welding in a forced position.

The welding method according to the invention can be mechani torch guidance or used under welding torch guidance by hand become.

The invention has been applied, for example, to the materials AlMgSi1 and AlMg3Mn the filler material S-AlSi5 applied.

Claims (10)

1. Shielding gas for TIG direct current welding of aluminum, aluminum materials and / or aluminum alloys comprising helium or a mixture of helium and argon, characterized in that the shielding gas either no helium and no argon and at least a portion of 275 vpm to 475 vpm nitrogen or in addition Helium and argon contains at least a proportion of 275 vpm to 500 vpm nitrogen. 2. Shielding gas according to claim 1, characterized in that the protective gas contains between 300 vpm and 450 vpm nitrogen. 3. Shielding gas according to claim 1 or 2, characterized in that the protective gas contains at least 45 vol .-% helium. 4. Shielding gas according to one of claims 1 to 3, characterized in that the Shielding gas contains 1 to 40 vol .-% argon. 5. Shielding gas according to one of claims 1 to 4, characterized in that the Shielding gas 0.01 to 1 vol .-% oxygen, carbon dioxide or a mixture of Contains oxygen and carbon dioxide, the protective gas in addition to helium and optionally, argon contains a proportion of 275 vpm to 500 vpm nitrogen. 6. Process for TIG direct current welding of aluminum, aluminum plant substances and / or aluminum alloys, with a protective gas of the welding point is supplied and the protective gas is helium or a mixture of helium and contains argon, characterized in that the protective gas either besides helium, no argon and at least a portion of 275 vpm to 475 vpm Nitrogen or in addition to helium and argon at least a proportion of 275 vpm to Contains 500 vpm nitrogen. 7. The method according to claim 6, characterized in that the protective gas contains between 300 vpm and 450 vpm nitrogen.   8. The method according to claim 6 or 7, characterized in that the protective gas contains at least 45 vol .-% helium. 9. The method according to any one of claims 6 to 8, characterized in that the Shielding gas contains 1 to 40 vol .-% argon. 10. The method according to any one of claims 6 to 9, characterized in that the Shielding gas 0.01 to 1 vol .-% oxygen, carbon dioxide or a mixture of Contains oxygen and carbon dioxide, the protective gas in addition to helium and optionally Argon contains a proportion of 275 vpm to 500 vpm nitrogen.