Oxford plasma cutters with welding guides: TIG welding is similar to to a MIG welder as it uses an electric arc in the same was as MIG welding does but differs in a few ways. Instead of a continuous spool of consumable wire, a TIG welder uses long tungsten welding rods that are manually slowly fed into the weld puddle to join the metal. TIG welding requires gas, usually argon, to protect and cool the weld puddle from external contamination. TIG welding is more suited to welding thinner materials such as stainless steel and aluminium as you can get the power down lower to reduce the risk of blow through and can even weld two dissimilar metals. Suitable for tricky welds such as S curves but TIG welders are still capable of welding heavier materials depending on the machine. TIG welding takes more practice that MIG welding as the process is much more manual with controlling the torch, welding rod and gas by hand (and foot for the gas) but once mastered will produce the highest quality welds making it the better choice where perfect, precise welds are required but due to the manual process is the least productive.

OXFORD HYBRID chopper machines such as the MULTI-ARC models, CUTMAKER PLASMA, TIGMAKER & PULSE MIG models (I-MIG DP & S-MIG DP) offer a really sensible alternative to the inverter. They are still built around a rugged copper wound transformer but the hybrid chopper technology used in these works to give you superior welding performance, the lowest power consumption & the very high efficiency means the transformer is around half the size & weight of an older type machine. The electronics are simple & operate at the welding voltage level i.e. under 80V, there is only one PCB fitted & no microprocessor to cause software faults. So to sum up you get all the performance benefits of a good inverter but reliability is superb & you can expect a really long life span, equivalent to old type transformer machines, many times that of any inverter! Read a few more details at Oxford Welder.

All welding requires the application of heat, which melts the metal being welded. With the TIG process, the heat comes from an electric arc that streams between the electrode in a hand-held torch and the metal being welded. The arc and molten metal are shielded by an inert gas, which protects the electrode and base metal from oxidizing. Filler rod is usually added to the puddle of molten metal as the weld progresses. The essence of making a good weld is heat control, which is governed by how you modulate the arc as it streams from the torch. Let’s look at this in detail.

Look for ways to create more efficiencies in the welding process. This includes examining such things as wire diameter, wire feed speed, voltage, travel speed, gas type, transfer mode, etc. For instance, if the shop is currently welding with a short arc process and a 75/25 blend of shielding gas, it may be more effective to switch to a different gas and a spray mode of transfer. Or, a change in process may be warranted based on the condition of the part. If there is oxide on the part, it may be easier to change to a process that will overcome contamination problems rather than try to clean each part before welding. Your welding supplier should be up to date on the latest technology and be able to advise you on new processes, machinery and consumables that can optimize welding at the shop. In some cases, it may be better to double bevel a joint to prepare it for welding rather than single bevel it. It is recommended to double bevel any material that is more than 3/4″ in thickness. Just this simple change in procedure can save quite a bit in weld metal. On a 3/4″ thick piece, a double bevel will use 1.45 lbs. per foot of weld metal while a single bevel will use 1.95 lbs. per foot. Explore a few more info on weldingsuppliesdirect.co.uk.