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East End Welding, Inc., Implements Robotic Submerged Arc Welding For Power Generation Application

Lincoln Electric, Automation Division

By Jeff Nadzam
Technical Sales Representative, Lincoln Electric

The use of a welding robot for welding fabrication usually employs a solid or metal cored electrode. This is true because of the versatility of the GMAW process – all-position capability, low heat input modes of metal transfer, higher deposition rates and electrode efficiency and an exceptionally low hydrogen weld deposit. The alternatives are generally not viewed as cost effective. 

An exception to this typical robotic weld process selection paradigm is submerged arc welding (SAW). It is embraced as a highly efficient welding process because of its ability to deliver sound weld deposits, which are lower in hydrogen and fuse well with parent materials. With certainty, SAW is able to deliver exceptional finished weld mechanical properties. For these reasons, many manufacturers in the ASME welding fabrication portion of the welding market prefer SAW and specify its use at every opportunity.

During a tour of Lincoln Electric Automation in Cleveland, John Susong, CEO and president of East End Welding, Inc. located in Brimfield, Ohio viewed with keen interest the use of the SAW process using a robotic welding arm.

 Robotic Subarc Welding

 Robotic Subarc Welding Cell Following the presentation, a lively debate ensued. Susong, who was accompanied to Lincoln Electric by Bob Einfeldt of Praxair Distribution, knew his operations had good reason to investigate the robotic use of SAW. Einfeldt reinforced the idea, and plans for employing the SAW robot welding system at East End Welding were born. 

Both Susong and Einfeldt recognized the important role SAW could play in East End’s future. The potential for robotically automated SAW became apparent to Susong as he grew aware of the benefits the submerged arc process provides in power generation fabrication. With this in mind, he began to seek ways to develop uses for SAW in his welding shop.

Susong’s goal was to spend more time on the power generation side of his fabrication business to improve operational efficiency and finished weld quality. The company’s end cap-to-header welding application suited that requirement and was an ideal target for integration of the robotic SAW process.

Factors for change
East End had been using SMAW instead of a higher operator factor welding process. As such, the welding was time consuming. Each end cap required a complete-penetration, multiple-pass weld and had pre-heat and interpass temperature requirements. Also, because of the pieces’ overall length, the header fabrication was prone to awkward over-handling. 

If the company were to switch to robotic submerged arc welding, welders could then rotate the torch head instead of rolling the headers during fabrication. Susong was sold, but he also recognized that careful planning was imperative to make this happen. He began to form his team to make the transition to the new robotic process. He knew that there was a risk to this type of investment but was willing to “blaze a trail” because, in the end, he would have a great tool, “that no one else in the world had.”

 East End Welding Inc.

 SAW Robotic System      

East End Welding first implemented the SAW robotic system in late 2009. The installation has a planned three area work cell capability, 90-degrees apart. It features the use of a FANUC® M-710 robot arm and control integrated with Lincoln Electric’s inverter-based Power Wave® AC/DC 1000® SD welding power source. A modified SAW welding head delivers a SAW single wire from a bulk package or coil of Lincolnweld® LA-90, LA-92, or LA-93, 3/32-inch diameter, solid-wire, submerged arc electrode, typically specified with Lincolnweld® 960 flux.  To ensure concentric flux coverage to the weld joint, the company used a Lincoln Electric patented air pressure delivery system.

 

Teamwork facilitates change
At East End, Susong empowers his team members to approach technology changes head on. From a training standpoint, when the company acquires the most recent advances in machining, cutting, and welding to improve finished product quality and reduce costs, he trusts his team to take advantage of every opportunity to develop the use of new technology. Susong believes that fostering a collaborative relationship between team members and key vendors is central to the successful implementation of the robotic system. 

When East End rolled out the new robotic SAW process, Susong invited Praxair and Lincoln Electric to be a part of his implementation team.  Lincoln Electric Automation’s David Mate was significant to the successful outcome. His technical hands-on approach provided new welding knowledge for the entire East End team, which included David Dockery, Doug Susong, Randy Starcher, Mike Benyi and Greg Murray.

Together, the team worked through the planning for the welding sequence, the issue of controlling heat input and interpass temperature and, finally, the consistent delivery of wire and flux to the weld joint. 

 Efficient Robotic SAW Process

 SAW Robotic Welding System

Lincoln Electric’s Mate worked through each aspect of the welding operations, and the combined effort of the East End team and Lincoln Automation turned a risk into a complete success, developing an efficient robotic process.

Integrating a new process
In the process, the end cap-to-header weldment’s root weld and the subsequent hot pass are prepared using GTAW in a manual operation that precedes the use of the SAW robotic welding system. Proper header welding requires the joining of two end caps per unit. Once the SAW weld is complete on one end, the 17-foot header is lifted from tooling and rotated 180 degrees to allow for the welding of the second end cap. Six header assemblies are placed in a unique East End-designed welding fixture that holds each end cap in the flat, 1G, welding position. This innovative fixture allows for robotic welding of the majority of header orders East End receives.

The robot moves from one end cap-to-header weldment to the next, one pass at a time, with up to 20 passes per end cap. This method allows for easier maintenance of the required interpass temperature (less waiting), as well as reduced cleaning of used flux between passes. All of the welding uses AC current for the fill passes and then AC or DC+ for the cap passes. One note: in this highly detailed application, the robotic welding operator has more to plan for and be aware of than is typical for a commercial non-code quality welding robot operation. 

The Lincoln Electric Power Wave® AC/DC 1000® SD, as interfaced with the 12.0 foot reach of the FANUC® M-710 robot, features the ability to manipulate how much DC- polarity (higher melt-off rates) is paired with DC+ (deeper penetration). As a result, the use of this feature reduces the risk of blowing through the TIG (GTAW) root and hot pass weld combination with SAW.  The Power Wave® AC/DC 1000® SD also allows the operator to adjust time and current magnitude during each half cycle and the frequency of the AC output.

Robotic Welding Applications 

Finished Weld Quality Depending on the wire selected, Lincolnweld® 960 or other Lincolnweld® submerged arc flux is fed through a Lincoln Electric patented pressurized, solenoid controlled, Weld Engineering® flux delivery and recovery system. The flux has a preconditioning temperature of 350°F.

With implementation of this system, finished weld quality improved while the time to make the finished welds diminished. The team’s hard, persistent effort paid off and advanced technology triumphed as the SAW welding system moved East End forward to meet the needs of its customers – efficiently and effectively – now, and into the future. 

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