![]() Compared to E70T-4, they offer slightly lower deposition rates of up to 30 pounds per hour, but they offer a smoother welding arc and Charpy impact toughness properties. The highest deposition rate gas-shielded flux-cored wire is E70T-1. This wire is also self-shielded, allowing it to be easily used outdoors. This wire is widely used to join thick steels where there is no Charpy impact toughness requirement. ![]() It offers the highest semi-automatic deposition rates, up to 40 pounds per hour. Since this wire is self-shielded, it is widely used outdoors and in field erection of structural steel.įor semi-automatic welding in the flat position, the fastest way to join thick steel plate is with an E70T-4. in the vertical-up position, 50% faster than other E71T-8 wires. Lincoln Electric's NR®-232 can deposit 4.5 lbs./hr. ![]() It is a top choice for shipbuilding, structural steel, and general steel fabrication applications.įor semi-automatic out-of-position welding without shielding gas, E71T-8 wires offer the highest deposition rates. These are reasons why E71T-1 is the world's most popular flux-cored wire. Argon/carbon dioxide blends are used for the smoothest arc and best out-of-position performance. In addition, the E71T-1 wires also offer an exceptionally smooth welding arc and minimal spatter, even with 100% carbon dioxide shielding gas. Its fast freezing rutile slag provides the highest deposition rates in the vertical-up position, up to 7 pounds per hour, unmatched by any other semi-automatic arc welding process. There are several popular types of flux-cored wires and how they can increase welding productivity:įor semi-automatic out-of-position welding, E71T-1 wires offer unsurpassed performance. They may be used outdoors in heavy winds without tenting and the additional equipment required for gas shielding. The benefits of self-shielded flux-cored wires lie in its simplicity. The core materials generate its own shielding gases, slag formers, and compounds to refine the weld pool. The FCAW-S wires on the other hand, the core materials must provide all of the shielding. As all of shielding is provided by the shielding gas, the core materials may be carefully selected to maximize a certain area of welding performance, such as obtaining smooth spray-type transfer with 100% carbon dioxide shielding gas and welding speeds twice as fast in the vertical position. The core ingredients for FCAW-G wires have been formulated to obtain performance impossible to achieve with a solid GMAW wire. The flux-cored arc welding self-shielded (FCAW-S) wires were introduced to the market later, around 1961. ![]() Scavengers and fluxing agents are used to refine the weld metal.įlux-cored arc welding gas-shielded (FCAW-G) wires were introduced to the market around 1957. Powdered alloys are added to produce low-alloy deposits or improving the mechanical properties. ![]() Iron powder is used to increase deposition rates. Slag formers are added to shield the weld pool and shape and support the weld. The ability to add a variety of materials to the core of the welding wire allows many performance enhancements to be made. It is either limited to short-circuit transfer, which is restricted by many welding codes due to the tendency for lack-of-fusion, or pulse transfer, requiring a special welding power source. For example, GMAW is slow for out-of-position welding. For many welding applications like vertical-up welding, flat welding, welding over galvanized, or welding hard-to-weld steels, a flux-cored wire can do it better and faster.Īlthough gas metal arc welding (GMAW) with a solid mild steel wire is popular, easy-to-use, and effective for many applications, it does have limitations and drawbacks. If welding with a solid wire is satisfactory, why use a higher priced flux-cored wire? A flux-cored wire is optimized to obtain performance not possible with a solid wire. ![]()
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