✳ by Pat Toensmeier b i g f u t u r e W e l d i n g i s a d y n a m i c i n d u s t r y w i t h a
A clever Bronze-Age worker wAs thinking outside the box one day 5,500 years ago when he came up with an inspired idea. A great way of making things with the bronze alloys that were being developed then, he reasoned, would be to heat them until they started melting and pound them together with a hammer. By combining heat and pressure in this way, craftsmen could make just about anything that required a strong metal like bronze.
This was the birth of welding, a pro-
cess that has had a major impact on metalworking and product engin- eering ever since.
Anything made of metal, no mat- ter how big or small, can be welded. Examples are everywhere, from vehicles like cars, trucks and motorcycles to rail cars, ships, aircraft, rockets and space stations. Construction is a huge market, and skyscrapers, bridges and highways would be impossible to build without welding, as would oil and natural-gas pipelines, offshore oil platforms, giant
wind turbines and solar panels. Weld- ers help install and maintain boilers, antipollution systems and other large structures, as well as piping for industri- al, commercial and residential facilities. Welding is even used by artists to create sculptures and decorative items.
There is almost no limit to what weld- ing can do, especially since developments in the technology continually improve its accuracy, quality and versatility. Welding is, in fact, an increasingly high-tech skill. Welders are being trained to operate
Staff Sgt. Nicole Lomax uses a gas metal arc (GMA) welding machine to weld a t-joint at Lackland Air Force Base, Texas.
photo left courtesy of u.s. air force, photo top right courtesy of edison Welding, photo bottom right courtesy of nasa
T h e r e a r e m a s p e c t s ny a t o w e l d i n g " . W h e n p e o p m e robots and other automated systems that use powerful lasers, electron beams and sometimes explosives to bond metals. The ability to work with computers and program software is consequently vital to the successful operation of these systems. i n c o n t a e co l c t w i t h i t , they love it." electrode. Its low-heat characteristic reduces distortion in thin metals, such as those used in aerospace. SMAW, also called “stick welding,” uses a flux-coated consumable electrode (“flux” is a chemi- cal cleaning agent that removes oxidation from the metals to be joined) and is pri- marily used for repair and steel welding. As the electrode burns, the flux disinte- grates, which releases a shielding gas that protects the weld from degradation. is usually in wire or stick form (though some welds don’t use fillers) to perma- nently bond metal pieces. Welding can also be used to cut and dismantle objects of all sizes as well as for repairs. Don Howard, a welding special- ist at Concurrent Technologies Corp., an engineering firm in Johnstown, Pa., estimates that 20%-25% of U.S. welding is automated and predicts this trend will grow by about 20% in the next few years. One common process is Gas Metal Arc Welding, or GMAW. In GMAW, an electrode, which is also the filler, is con- tinuously fed through the nozzle of an arc torch. When the welder activates the torch, several operations take place: The electrode begins feeding through the “A lot of very intelligent people are coming into the welding community,” says Howard. There is money to be made, he notes, but the industry also offers career paths. “Welding is not just about In more advanced welding technolo- gies, lasers are combined with GMAW in a hybrid process to make what one expert calls “scalpel-like cuts” that are up to ½-inch deep, narrow and extremely precise. The GMAW part of the process then deposits the filler and melts it with a secondary heat source. working on a manufactur- ing line anymore. Once in the industry, people know they can find a niche.” nozzle, a direct current is generated that creates an arc when it comes in con- tact with the workpiece and shielding gases are released around the nozzle to protect the weld from atmospheric gases that could degrade its quality. The arc, whose move- ment the welder controls, consumes the electrode and fills in the weld joint, which creates the weld. Other widely used techniques like Gas Tungsten Arc Welding (GTAW) and Shielded Metal Arc Welding (SMAW) are variations of the process. GTAW, for example, is a relatively low-heat method that uses a non-consumable tungsten “These are good times to be in welding,” says Patricio Mendez, director of the Canadian Center for Welding and Joining at the University of Edmonton in Alberta, Canada. Mendez notes that students who like designing and build- ing with metal and are The influence of welding is so broad that many of the product designs and building techniques people take for granted would not be possible without it. With demand for skilled welders rising and the technology of welding becom- ing more advanced, especially where automation is concerned, students have a unique opportunity to learn a career that can be shaped around their interests. Jay Eastman an engineer at the Edison Welding Institute operates a laser-weld bonding machine. interested in fields such as materials engineering, robotics, lasers, computer programming and systems integration will find plenty of career opportunities in welding. “There are many aspects to welding,” Mendez says. “When people come in contact with it, they love it.” ✳ Many students are being introduced to the process with the help of virtual welding devices. Edison Welding Institute (EWI) of Columbus, Ohio, and Lincoln Electric of Cleveland, Ohio have devel- oped virtual welding devices that are designed to teach the basics of welding in classrooms. The EWI system uses sensors that duplicate the look and feel of weld- ing. Lincoln’s system includes a torch with sensors and a welding mask with special lenses that create realistic images of welding applications.
There are more than 80 welding processes. Most involve a skilled worker using a high-heat torch (2,800-plus degrees Fahrenheit), filler material that
A mission specialist working on the International Space Station performs extravehicular activities, putting welding to work to connect power, data and cooling cables.
Careers in Welding | 3