NO790240L - WELDING ELECTRODE. - Google Patents

Description

The present invention relates to a welding electrode for welding cast iron. In particular, the invention relates to a welding electrode for high-voltage arc welding comprising a core wire of a nickel-iron alloy and equipped with a metal coating and further comprising a flux.

This electrode can be used with alternating current or

direct current without overheating.

Until now, it has been known that electrodes with a ferrous alloy core for welding cast iron become very hot during welding deposition. According to the state of the art, these electrodes sometimes become so hot that the electrode coating breaks down after 2/3 of the electrode has been consumed, so that the remaining electrode is rendered unusable and must be discarded. Moreover, these prior art electrodes are sensitive to treatment due to susceptibility to severe overheating. These shortcomings are significant as cast iron electrodes with a nickel-iron core offer many significant advantages when welding cast iron, and as they are frequently used for this purpose.

The purpose of the present invention is to provide an electrode for high-voltage arc welding which does not exhibit the hitherto existing defects, and the invention thus relates to a welding electrode for high-voltage arc welding comprising a core wire of a nickel-iron alloy with greatly reduced superheating during welding, where the core wire has a metal coating chosen from among copper, silver and alloys thereof, and this welding electrode is characterized by the fact that the metal coating is again coated with a welding flux with a composition in % by weight of up to 25% nickel powder, 4-18% nickel-coated magnesium powder, 18-

47% of an alkaline earth metal carbonate, 5-18% of an antioxidant, up to 11% iron powder, 2-13% copper powder, 7-11% calcium-

fluoride, 4-24% carbon substances, 1-6% clay, which welding flux is mixed with sodium or potassium silicate binder in an amount from 40-50% of the total flux coating, which welding flux constitutes from 18-52% of the total electrode weight.

In recent times, attempts have been made to arrive at a truly superior welding electrode for welding "cast iron. Of particular importance was the desire to produce an electrode of the nickel-iron type for use on cast iron, which was not seriously overheated by welding deposition.

After extensive research, it was discovered that electrodes according to the invention with nickel-iron cores, but on the surface surrounded by a thin layer of an alloy with high conductivity, such as copper and silver alloys, gave considerably reduced overheating. "Nickel-iron", as used herein, means alloys containing iron and nickel, such that the nickel content is between 40 and 65% by weight.

On further investigation, it was found that the thickness of the conductive outer layer of silver or copper alloy, placed on the outer cylindrical surface of the core wire which gave the best results according to the invention, could be defined within a range which can be determined in the following way:

Minimal thickness of the conductive layer

in mm = 0.013 . (the diameter of the core

thread in mm)

Maximum thickness of the conductive layer

in mm = 0.019 . (the diameter of the core

the thread in mm).

For the person skilled in the art, it will be clear that conductive layers of pure copper or pure silver give optimal results, but also that silver alloyed with other elements and copper alloyed with other elements will give acceptable results where the thermal conductivity of the resulting alloy is not drastically affected .

A typical welding electrode of this type consists of

the following items:

A core rod of an alloy of nickel and iron with mainly 58-60% nickel by weight. The entire outer cylindrical surface of the core is equipped with a layer of copper. If it is assumed that the core has a diameter of 3.17 mm, the thickness of the surface copper layer on the basis of the aforementioned mathe- ical equations, lie within the range 0.043 mm to 0.061 mm. The copper layer can be applied to the core surface using several different methods, well known in the art, such as electrolysis or spraying.

According to the invention, a flux coating is distributed on the core of the electrodes. The amount of the flux coating in % by weight of the electrode according to the invention, compared to the total weight of the electrode is as follows:

Examples of wide and preferred areas of the flux coating according to the invention are as follows, expressed in % by weight:

As is well known, in the state of the art, the flux coating is provided with a suitable binder such as sodium silicate or potassium silicate to support adhesion to the electrode core. The binder is mixed with the flux in amounts corresponding to 40-50% by weight binder, calculated on the total flux coating.

During welding deposition it was found that the electrodes

according to the invention deposited welding deposits with nodular graphite. This is remarkable as the presence of the nodular graphite in the weld deposits not only gives a structure which is

highly desirable for cast iron, but this structure also indicates maximum ductility in the weld metal deposit. The electrodes according to the invention also have extremely good weldability properties for positioning and out-of-position welding. Furthermore, when welding, these electrodes provide a soft welding arc and an even electrode burn, and they do not sink into the cast iron base metal during welding deposition, thus resulting in minimal base metal penetration and dilution, which are usually greater problems when welding cast iron. Furthermore, the electrode welding deposits provided particularly good slag coverage, with solid and aesthetically good-looking welding deposits.

As mentioned above provides. the flux according to the invention together with the welding rod a very good joint containing nodular graphite. This is because the flux contains nickel-coated magnesium, which is a nodulating agent for graphite.

Furthermore, the carbon content in the flux is relatively high, 4-20% by weight, which supports a fluid welding deposit. However, to avoid the formation of graphite flakes in the weld deposit, which weakens the weld seam, magnesium is included in the flux to effectively nodulate the graphite.

The magnesium particles are nickel-coated to protect magnesium from oxidizing during welding, so that a graphitic nodular structure can be effectively achieved in the weld seam. In addition, the flux also contains deoxidizers that protect magnesium.

The other components listed above in the flux, i.e. alkali metal carbonate, calcium fluoride, clay, etc., also act as a protective cover to enable the desired reactions to take place in the weld. For example, the flux ensures copper absorption in the welding deposit and also increases the fluidity of the welding alloy.

The flux according to the invention thus offers numerous advantages both with a view to regulating the metallurgical reactions in the molten welding deposit to form a nodular structure which is very ductile, as well as with a view to a smooth and smooth deposit.

Of particular importance is the advantage that the electrode according to the invention can be used with the use of both alternating current and direct current. During welding deposition, the electrodes thus work considerably colder than electrodes for welding cast iron according to the state of the art. The electrodes according to the invention can be used 100% without accompanying overheating problems.

Claims (1)

Welding electrode for extensive high-voltage arc welding a core wire of a nickel-iron alloy with greatly reduced overheating during welding, where the core wire has a metal coating selected from copper, silver and alloys thereof, characterized in that the metal coating is again coated with a welding flux with a composition in % by weight of up to 25 % nickel powder, 4-18% nickel-plated magnesium powder, 18-47% of an alkaline earth metal carbonate, 5-18% of an antioxidant, up to 11% iron powder, 2-13% copper powder, 7-11% calcium fluoride, 4-24% carbon substances, 1-6% clay, which welding flux is mixed with sodium or potassium silicate binder in an amount from 40-50% of the total flux coating, which welding flux constitutes from 18-52% of the total electrode weight.