The characteristic features and principal causes of reheat cracking are described. General guidelines on best practice are given so that we...
The characteristic features and principal causes of reheat cracking are described. General guidelines on best practice are given so that welders can minimise the risk of reheat cracking in welded fabrications.
Visual appearance
Reheat cracking may occur in low alloy steels containing alloying additions of chromium, vanadium and molybdenum when the welded component is being subjected to post weld heat treatment, such as stress relief heat treatment, or has been subjected to high temperature service (typically 350 to 550°C).
Cracking is almost exclusively found in the coarse grained regions of the heat affected zone (HAZ) beneath the weld, or cladding, and in the coarse grained regions within the weld metal. The cracks can often be seen visually, usually associated with areas of stress concentration such as the weld toe.
Cracking may be in the form of coarse macro-cracks or colonies of micro-cracks.
A macro-crack will appear as a 'rough' crack, often with branching, following the coarse grain region, ( Fig. 1a). Cracking is always intergranular along the prior austenite grain boundaries ( Fig. 1b). Macro-cracks in the weld metal can be oriented either longitudinal or transverse to the direction of welding. Cracks in the HAZ, however, are always parallel to the direction of welding
Fig. 1a. Cracking associated with the coarse grained heat affected zone |
Fig. 1b. Intergranular morphology of reheat cracks |
Micro-cracking can also be found both in the HAZ and within the weld metal. Micro-cracks in multipass welds will be found associated with the grain coarsened regions which have not been refined by subsequent passes.
Causes
The principal cause is that when heat treating susceptible steels, the grain interior becomes strengthened by carbide precipitation, forcing the relaxation of residual stresses by creep deformation at the grain boundaries.
The presence of impurities which segregate to the grain boundaries and promote temper embrittlement, e.g. sulphur, arsenic, tin and phosphorus, will increase the susceptibility to reheat cracking.
The joint design can increase the risk of cracking. For example, joints likely to contain stress concentration, such as partial penetration welds, are more liable to initiate cracks.
The welding procedure also has an influence. Large weld beads are undesirable, as they produce a coarse grained HAZ which is less likely to be refined by the subsequent pass, and therefore will be more susceptible to reheat cracking.
Best practice in prevention
The risk of reheat cracking can be reduced through the choice of steel, specifying the maximum impurity level and by adopting a more tolerant welding procedure / technique.
Steel choice
If possible, avoid welding steels known to be susceptible to reheat cracking. For example, A 508 Class 2 is known to be particularly susceptible to reheat cracking, whereas cracking associated with welding and cladding in A508 Class 3 is largely unknown. The two steels have similar mechanical properties, but A508 Class 3 has a lower Cr content and a higher manganese content.
Similarly, in the higher strength, creep resistant steels, an approximate ranking of their crack susceptibility is as follows:
5 Cr 1Mo lower risk 2.25Cr 1 Mo â 0.5Mo B â 0.5Cr 0.5Mo 0.25V higher risk
Thus, in selecting a creep resistant, chromium molybdenum steel, 0.5Cr 0.5Mo 0.25V steel is known to be susceptible to reheat cracking but the 2.25Cr 1Mo which has a similar creep resistance, is significantly less susceptible.
Unfortunately, although some knowledge has been gained on the susceptibility of certain steels, the risk of cracking cannot be reliably predicted from the chemical composition. Various indices, including rG1, P SR and Rs, have been used to indicate the susceptibility of steel to reheat cracking. Steels which have a value of rG1 of less than 2, P SR less than zero or Rs less than 0.03, are less susceptible to reheat cracking
rG1 = 10C + Cr + 3.3Mo + 8.1V - 2 P SR = Cr +Cu + 2Mo + 10V +7Nb + 5Ti - 2 Rs = 0.12Cu +0.19S +0.10As + P +1.18Sn + 1.49Sb
Irrespective of the steel type, it is important to purchase steels specified to have low levels of impurity elements (antimony, arsenic, tin, sulphur and phosphorus).
Welding procedure and technique
The welding procedure can be used to minimise the risk of reheat cracking by
Fig. 2a. Welding in the flat position high degree of HAZ refinement |
Fig.2b. Welding in the horizontal/vertical position low degree of HAZ refinement |
- Producing the maximum refinement of the coarse grain HAZ
- Limiting the degree of austenite grain growth
- Eliminating stress concentrations
The procedure should aim to refine the coarse grained HAZ by subsequent passes. In butt welds, maximum refinement can be achieved by using a steep sided joint preparation with a low angle of attack to minimise penetration into the sidewall, ( Fig 2a). In comparison, a larger angle V preparation produces a wider HAZ, limiting the amount of refinement achieved by subsequent passes, ( Fig 2b). Narrow joint preparations, however, are more difficult to weld, due to the increased risk of lack of sidewall fusion.
Refinement of the HAZ can be promoted by first buttering the surface of the susceptible plate with a thin weld metal layer using a small diameter (3.2mm) electrode. The joint is then completed using a larger diameter (4 - 4.8mm) electrode which is intended to generate sufficient heat to refine any remaining coarse grained HAZ under the buttered layer.
The degree of austenite grain growth can be restricted by using a low heat input. However, precautionary measures may be necessary to avoid the risk of hydrogen assisted cracking and lack-of-fusion defects. For example, reducing the heat input will almost certainly require a higher preheat temperature to avoid hydrogen assisted cracking.
The joint design and welding technique adopted should ensure that the weld is free from localised stress concentrations which can arise from the presence of notches. Stress concentrations may be produced in the following situations:
- welding with a backing bar
- a partial penetration weld leaving a root imperfection
- internal weld imperfections such as lack of side-wall fusion
- the weld has a poor surface profile, especially sharp weld toes
The weld toes of the capping pass are particularly vulnerable, as the coarse grained HAZ may not have been refined by subsequent passes. In susceptible steel, the last pass should never be deposited on the parent material, but always on the weld metal, so that it will refine the HAZ.
Grinding the weld toes with the preheat maintained has been successfully used to reduce the risk of cracking in 0.5Cr 0.5Mo 0.25V steels.
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