Gas purging for defect free welds
Effective gas purging to avoid porosity This article from Huntingdon Fusion Techniques (HFT) describes the different purging options for achieving defect-free welds.
T he production of defect-free welds is crucial, particularly if high strength is required. The presence of poros- ity, in particular, can lead to a significant reduction in mechanical properties. This leads to inevitable joint failure, which then results, at best, to costly repair work with production interruptions that can be even more expensive. And in the worst scenario, injury and loss of life is possible. Gases such as hydrogen, oxygen and nitrogen are soluble in many liquid metals. As the metal cools and eventually solidifies, the solubility decreases and the gas is then released causing porosity. The principal gases that cause porosity vary depending on the material being welded. In carbon steels hydrogen, nitrogen and oxygen are all soluble, while in stainless steel and aluminium alloys, hydrogen is the usual culprit. Hydrogen and nitrogen can both cause porosity in copper-based alloys but most nickel-based materials are only sus- ceptible to nitrogen. To prevent porosity forming during fu- sion welding it is essential that hydrogen, oxygen and nitrogen are excluded from the weld environment. This is best achieved by displacing these gases by flushing with an inert gas such as argon, which is far less soluble than most other gases in liquid metal. This process is referred to as purging. In circumstances where welds have to be designed to withstand stress in service, special consideration needs to be given to their metallurgy and profiles. The me- chanical properties of welds, particularly their fatigue properties, can be influenced significantly by their shape and composi- tion. In particular, at the weld root, a posi- tive reinforcement combined with smooth transition from weld to base metal is a
pre-requisite to achieve optimum mechani- cal strength. Joints of high quality between cylindri- cal sections such as tubes and pipes can only be made by ensuring that atmospheric gases are eliminated and positive, smooth weld reinforcement is provided. The presence of oxygen and to a lesser extent nitrogen around the molten weld can lead to wide-ranging defects. Discolor- ation is unsightly and, in some instances, might indicate metallurgical imbalance, especially with many stainless steels. Gross oxidation inevitably results in a reduction of mechanical properties and can cause catastrophic loss of corrosion resistance. Nitrogen contamination can result in brit- tleness, while gas porosity in the weld may give rise to cracking during or after cooling. It is clear that a reduction in weld sec- tion at the root, as evidenced by a concave geometry, will reduce the joint strength. Perhaps not so evident, but in many ap- plications of crucial importance, is the presence of notches or cracks, which tend to appear at the interface between the weld metal and the base material. These can propagate in service and cause failure. Basic Principles Weld root quality when making tubular joints can be ensured by applying appropri- ate safeguards based on the displacement of air from the fusion zone using an inert gas. This is achieved by gas purging, and the general principles are shown in Figure 1. Purging gases and procedures The most commonly used purging gas in Europe is commercial quality argon; in the US, however, helium has been in more general use. The materials being joined and the
Figure 2: Soluble weld purge film being applied to a pipe end. welding process used are two main factors in the selection of the optimum inert gas or gas mixture. Purge gas flow rate and pressure also need to be established and, once selected, they should be included in the formal welding procedure. Variation in purge gas quality may arise during welding and it may be desir- able to apply continuous gas monitoring, especially to control oxygen and moisture content. For this purpose, dedicated Weld Purge Monitors® and Dewpoint Monitors are commercially available. The first requirement for successful purging is to provide gas entry and exit points. Gas is fed through one end seal with an exit hole at the other end. Argon has a greater density than air and the gas inlet should be at a lower elevation than the exhaust, so that air is expelled effectively from the pipe bore. The converse applies to helium, which is less dense than air. On small pipes and tubes, where the internal volume is small, the cost of continuous flow purging may not be sig- nificant. However, problems can arise due to turbulence inside the tube, making air displacement difficult. The most effective purging systems are those that locate seals either side of the joint and displace air with an inert gas, while at the same time monitoring potentially damaging residual gases such as oxygen and hydrogen to ensure that they
Figure 1: Schematic illustration showing pipe end seals between which air can be displaced and replaced with an inert gas.
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July 2022
AFRICAN FUSION
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