Several years ago Henry was the maintenance manager at a large manufacturing facility. He was married, had a very upbeat personality, a good position at the company, and was pleasant to be around. One day, Henry was trying to track down a low voltage problem and was conducting voltage measurements on a 4,160V to 480V dry type transformer on an upper level mezzanine. He took off the transformer cover, knelt down in front of it with a meter to test the 480V side and got the 4,160V side by mistake. The resulting arc flash explosion sent a fireball blasting out of the cabinet catching him in the torso and groin before rolling up his face.
With his clothes burning, Henry managed to make it down the ladder. Coworkers put out the fire and rushed him to hospital where he was diagnosed with third degree burns over a large portion of his body. He lingered in the hospital for an agonizing seven days and then died.
“From that moment, the way I viewed electrical power changed forever,” says Jim Phillips, who was called in to conduct the forensic investigation the next day. Today Jim is one of America’s foremost experts on Arc Flash and teaches numerous seminars on electrical safety through his company Brainfiller, Inc. (formerly T2G Technical Training Group) and has written a book on the subject that will be published in the fall. “If you work in this business long enough, you either know an arc flash victim or you know someone that knows a victim.”
According to a report compiled by Capelli-Schellpfeffer, Inc., five to 10 arc flash explosions happen in the USA every day, resulting in 1 to 2 deaths. Moreover, over the course of a seven-year study tracking electrical accidents conducted by the U.S. Department of Labor’s Bureau of Labor Statistics, 2,576 U.S. workers died and another 32,807 were injured — losing an average of 13 days away from work — due to electrical shock or burn injuries. A second study involving more than 120,000 employees determined arc flash injuries accounted for 77% of all recorded electrical injuries.
What is Arc Flash?
As defined by IEEE and the National Fire Prevention Association (NFPA), an Arc Flash is a strong electric current – and often a full-blown explosion – that passes through air when insulation between electrified conductors is no longer sufficient to contain the voltage within them. This creates a “short cut” that allows electricity to race from conductor-to-conductor… to the extreme detriment of any worker standing nearby.
Arc Flash resembles a lightning bolt-like charge, emitting extreme heat – up to 35,000 degrees Fahrenheit or four times the surface temperature of the sun. Anyone exposed to the blast or heat without sufficient personal protective equipment (PPE) would be severely — and often fatally — injured.
Arc Flash incidents cause several types of injury. Like Henry, victims may be burned. They may also be thrown by the force of the explosion sustaining impact injuries such as concussions and fractures, and/or deafened by the bang, which can reach 160 decibels – louder than a jet engine. The extreme heat of the explosion may also melt and shatter metal wiring and equipment and spray it across the room as projectiles, causing shrapnel wounds, burns and igniting clothing.
According to most studies, the most common cause of these accidents is human error. Henry’s tragic mistake in measuring the wrong side of the cabinet is a case in point. But many other factors may trigger an incident. In some cases just coming too close to a high-current source with a conductive object can cause the electricity to flash over. Other causal factors include equipment failure due to use of substandard parts, improper installation, or even normal wear and tear, breaks or gaps in insulation or dust, corrosion or other impurities on the surface of the conductor.“It’s practically impossible to completely eliminate arc flash incidents,” says Greg Richards, an automation consultant with Siemens Energy & Automation. “The best way to avoid an Arc Flash incident is to avoid working on energized equipment, but that’s not always realistic,” adds Richards. “If you are in a continuous process environment or a facility like an Air Traffic Control tower then you may just have to deal with it.”
“However, there are a number of ways you can significantly reduce the risk, starting with understanding how dangerous these incidents can be, performing all the proper groundwork as outlined by IEEE and NFPA regulations (see NFPA 70E “Standard for Electrical Safety in the Workplace” and IEEE 1584 “IEEE Guide for Performing Arc Flash Calculations”) and making sure that when you do work on live equipment you have the appropriate PPE on at all times.”
Richards has his own Arc Flash horror story. Prior to joining Siemens he worked in a plant where a worker got seriously hurt checking the voltage on a circuit to make sure it had enough power to drive another piece of equipment. “He had second and third degree burns from the waist up. He was in the hospital for nearly a year and needed multiple skin grafts.”
This incident led to the creation of an Arc Flash task force for the company’s five North American plants. “We started with making sure we had the right PPE, but then we went looking for ways to eliminate Arc Flashes altogether.”
Eventually Richards realized that reducing the need to open the cabinet in the first place was one of the best ways to accomplish that goal. “People open the cabinet for many reasons, but chief amongst them is that, typically, they don’t know what’s going on inside,” he says. “They know there’s a problem; they are getting an alarm or a circuit has tripped or something. But they don’t know exactly what. What if we can get that information without opening the cabinet?”
By integrating all the relevant equipment, such as the motors, drives and switchgear, with the communications network in what Siemens calls a Totally Integrated Automation (TIA) architecture, operators are able to monitor and pull diagnostic information, perform trend and root cause analysis and generally better see what the problems are before sending an electrician into the plant to deal with a problem. Over time Richards found that workers were going into the electrical cabinet less and less often.
“As we used it more, the guys learned to trust the information they were getting,” Richards said. “If a breaker tripped, they knew it. But, before the TIA system, there was nothing to do but reset the breaker. The TIA diagnostics allowed engineers to go back and trend the data—to perform and process the diagnostics externally. For example, if I wanted to know what the drive current was, I could just look that up. As a result, we found that, over time, people were going into the cabinet less and less.”
Phillips agrees that the TIA approach is solid. “If there are ways to monitor and control things that keep people from opening the cabinet then that’s a much better way. The best option is always to avoid the hazard. Doing this through automation and control is a great approach.”
“Having access to this data does not stop arc flash,” cautions Richards. “The number one thing you can do to avoid that is to coordinate your power system and reduce your exposure to a potential incident. And the more you integrate, the less likely you are to have to open the cabinet in the first place.”
Jim Phillips – Brainfiller, Inc.
Greg Richards – Siemens Automation
Originally Published – Siemens Tuesday, August 4, 2009