- corrosion resistance
- heat resistance and high temperature properties
- low temperature properties
Types of nickel alloys are identified and guidance is given on welding processes and techniques which can be used in fabricating nickel alloy components without impairing their corrosion or mechanical properties or introducing flaws into the weld.
Material types
The alloys can be grouped according to the principal alloying elements. Although there are National and International designations for the alloys, tradenames such as Inconel and Hastelloy, are more commonly used.
In terms of their weldability, these alloys can be classified according to the means by which the alloying elements develop the mechanical properties, namely solid solution alloys and precipitation hardened alloys. A distinguishing feature of precipitation hardened alloys is that mechanical properties are developed by heat treatment (solution treatment plus ageing) to produce a fine distribution of particles in a nickel-rich matrix.
Solid solution alloys
Solid solution alloys are pure nickel, Ni-Cu alloys and the simpler Fe-Ni-Cr alloys. These alloys are readily fusion welded, normally in the annealed condition. As the heat affected zone (HAZ) does not harden, heat treatment is not usually required after welding.
Precipitation hardening alloys
Precipitation hardening alloys include Ni-Cu-Al-Ti, Ni-Cr-Al-Ti and Ni-Cr-Fe-Nb-Al-Ti. These alloys may susceptible to post-weld heat treatment cracking.
Weldability
Most nickel alloys can be fusion welded using gas shielded processes like TIG or MIG. Of the flux processes, MMA is frequently used but the SAW process is restricted to solid solution alloys and is less widely used.
Solid solution alloys are normally welded in the annealed condition and precipitation hardened alloys in the solution treated condition. Preheating is not necessary unless there is a risk of porosity from moisture condensation. It is recommended that material containing residual stresses be solution-treated before welding to relieve the stresses.
Post-weld heat treatment is not usually needed to restore corrosion resistance but thermal treatment may be required for precipitation hardening or stress relieving purposes to avoid stress corrosion cracking.
Filler alloys
Filler composition normally matches the parent metal. However, most fillers contain a small mount of titanium, aluminium and/or niobium to help minimise the risk of porosity and cracking.
Filler metals for gas shielded processes are covered in BS EN 18274:2004 and in the USA by AWS A5.14. Recommended fillers for selected alloys are given in the table.
| Table 1: Filler selection for nickel alloys |
|---|
| Parent Alloy | Filler designations | Comments |
|---|
| Alloy | BS EN ISO 18274 | AWS A5.14 | Trade names | |
|---|
| Pure nickel |
|
|
|
|
| Nickel 200 |
Ni 2061 |
ERNi-1 |
Nickel 61 |
Matching filler metal normally contains 3%Ti |
| Nickel Copper |
|
|
|
|
| Alloy 400 |
Ni 4060 |
ERNiCu-7 |
Monel 60 |
Matching filler metal contains additions of Mn, Ti and Al |
| Nickel Chromium |
|
|
|
|
| Brightray S |
Ni 6076 |
- |
NC 80/20 |
Ni-Cr and Ni-Cr-Fe filler metals may be used |
| Nimonic 75 |
Ni 6076 |
- |
NC 80/20 |
| Nickel-Chromium-Iron |
|
|
|
|
| Alloy 800 |
Ni 6625 |
ERNiCrMo-3 |
Inconel 625
Thermanit 21/33 |
Usually welded with Ni-Cr-X alloys, but more nearly matching consumables are available which contain higher C and also Nb |
| Alloy 600 |
Ni 6082 |
ERNiCr-3 |
Inconel 82 |
Matching filler metal contains Nb addition |
| Alloy 718 |
Ni 7718 |
ERNiFeCr-2 |
Inconel 718 |
Matching filler metal is normally used but Alloy 625 is an alternative consumable , if postweld heat treatment is not applied |
| Nickel-Chromium-Molybdenum |
|
|
|
|
| Alloy 625 |
Ni 6625 |
ERNiCrMo-3 |
Inconel 625 |
Filler metal is also used widely for cladding and dissimilar welds |
| Hastelloy C-22 |
Ni 6022 |
ERNiCrMo-10 |
Hastelloy C-22 |
|
| Nickel-Molybdenum |
|
|
|
|
| Hastelloy B-2 |
Ni 1066 |
ERNiMo-7 |
Hastelloy B-2 |
Corrosion resistant alloys require matching fillers |
Imperfections and degradation
Nickel and its alloys are readily welded but it is essential that the surface is cleaned immediately before welding. The normal method of cleaning is to degrease the surface, remove all surface oxide by machining, grinding or scratch brushing and finally degrease.
Common imperfections found on welding are:
- porosity
- oxide inclusions and lack of inter-run fusion
- weld metal solidification cracking
- microfissuring
Additionally, precautions should be taken against post-welding imperfections such as:
- post-weld heat treatment cracking
- stress corrosion cracking
Porosity
Porosity can be caused by oxygen and nitrogen from air entrainment and surface oxide or by hydrogen from surface contamination. Careful cleaning of component surfaces and using a filler material containing deoxidants (aluminium and titanium) will reduce the risk.
When using argon in TIG and MIG welding, attention must be paid to shielding efficiency of the weld pool including the use of a gas backing system. In TIG welding, argon-hydrogen gas mixtures tend to produce cleaner welds.
Oxide inclusions and lack of inter-run fusion
As the oxide on the surface of nickel alloys has a much higher melting temperature than the base metal, it may remain solid during welding. Oxide trapped in the weld pool will form inclusions. In multi-run welds, oxide or slag on the surface of the weld bead will not be consumed in the subsequent run and may cause lack of fusion imperfections.
Before welding, surface oxide, particularly if it has been formed at a high temperature, must be removed by machining or abrasive grinding; it is not sufficient to wire brush the surface as this serve only to polish the oxide. During multipass welding, surface oxide and slag must be removed between runs.
Weld metal solidification cracking
Factors which control solidification cracking include alloy, welding process and welding conditions. For example, solidification cracking is a factor which limits the application of submerged arc welding, both with respect to applicable alloys and welding conditions. More generally, this type of cracking leads to restriction of weld shape, welding speed and technique.
Microfissuring
Similar to austenitic stainless steel, nickel alloys are susceptible to formation of liquation cracks in reheated weld metal regions or parent metal HAZ. This type of cracking is controlled by factors outside the control of the welder such as grain size or impurity content. Some alloys are more sensitive than others. For example, some cast superalloys are difficult to weld without inducing liquation cracks.
Post-weld heat treatment cracking
This is also known as strain-age or reheat cracking. It is likely to occur during post-weld ageing of precipitation hardening alloys but can be minimised by pre-weld heat treatment. Solution annealing is commonly used but overageing gives the most resistant condition. Alloy 718 alloy was specifically developed to be resistant to this type of cracking.
Stress corrosion cracking
Welding does not normally make most nickel alloys susceptible to weld metal or HAZ corrosion. However, when Alloy 400 will be in contact with caustic soda, fluosilicates or HF acid, stress corrosion cracking is possible. For such service, thermal stress relief is applied after welding.
Stress corrosion can also occur in Ni-Cr alloys in high temperature water. High chromium filler metal has been developed for welds and overlays in this environment.
This Job Knowledge article was originally published in Connect, November/December 1996. It has been updated so the web page no longer reflects exactly the printed version.