Electronic Gas-Spring Pressure Monitors
Three different and unique applications—in-die assembly, in-die welding and deep drawing—all paint the same picture, illustrating how digital nitrogen-gas pressure monitors can improve quality and productivity. First, consider the U.S. Army’s desire to build a better bullet, and the creative solution provided by its primary small-caliber supplier, Lake City Army Ammunition Plant, operated by Alliant Techsystems (ATK), Independence, MO. Lake City is the Army’s largest supplier of small-caliber ammunition, the lone survivor among a supply chain that once numbered a dozen different companies. In the last several years—and particularly since 9/11—ATK has seen its production volumes jump to 1.4 billion small-caliber rounds/yr., tripling its output since 2000.
Forming and assembling the new rounds in the Waterbury presses requires ATK to take production-process control to new heights. Its ongoing Green Ammo program eventually will comprise a range of EPR sizes manufactured on 24 presses. To date the firm has completed upgrades to 12 BAMs for one of the EPR products—the M855A1 5.56 x 45 bullet, which has been used in Afghanistan since the spring of 2010.
The rounds are manufactured on 12 Waterbury presses, each outfitted with 14-station dies. Bowl-fed copper-alloy cups that enter the die are drawn over several stations to become the bullet jacket. As the drawn cups move through the die, the penetrator gravity-feeds into the jacket. Trim stations follow, then an ogive sizing and assembly station, additional sizing stations and a final cannelure or knurl station. Presses stroke at 60 hits/min.
“The design engineers that developed the process specified that we must closely monitor and track gas-spring forces in the die,” says ATK engineer John Segovia. “Insufficient force (from a leak in the nitrogen-gas supply system, for example) or over-pressurized gas springs trigger a press shutdown before out-of-specification bullets are fabricated.
“When we launched the program (early in 2008),” continues Segovia, “we installed electronic load cells to meet this requirement—four load cells in each BAM. However, we quickly realized that the load cells were too complicated for our manufacturing environment.”
“We had to find a better, most cost-effective, reliable and accurate solution for monitoring the spring forces,” says Segovia. To replace the load cells, Segovia opted to install electronic pressure monitors (from Dadco). Each of the 12 BAMs that have been upgraded for the Green Ammo program now boasts four pressure transmitters connected to nitrogen-gas springs, and a central control panel mounted on the press ram. The pressure monitors provide a 22-lbf resolution, offering significantly more process control compared to the 316-lbf resolution of the load cells.
To fit ATK’s presses, Dadco customized the die springs to mount the M6 port in the center rather than on the side, “a key factor to the success of the project,” says Segovia. “Our press rams are designed such as there is no room to go left or right—they’re all set up for vertical motion. All of the lines going to the control panel had to go through the top of the ram. We drilled a hole through the top of each ram to accommodate the lines.”
Since installing the electronic pressure monitors, maintenance issues are nonexistent, maximizing press uptime. And the facility is busy preparing a dozen or so additional BAMs similarly to continue to support the Army’s EPR programs.
Perfect In-Die Weld Pressure
Resistance-weld quality hinges on three key process variables—time, pressure and current. When welding inside a stamping die, pressure often proves the most difficult variable to control. Metal stamper GR Spring & Stamping, understands this well—well-versed in in-die welding, 30 of its dies include in-die nut-welding stations. On larger dies, the firm pipes nitrogen-gas springs together so it can pump up and dial down weld pressure as needed. Measuring and monitoring gas pressure initially fell to analog switches, which would trigger press shutdowns if nitrogen pressure dropped beyond an allowable setpoint, perhaps due to a worn spring or a leaky tubing connection.
“While the pressure switches were better than nothing,” says toolmaker Wade Pennington, “hysteresis on the switches often was significant. We needed a narrower tolerance range on gas pressure to ensure good-quality welds.”
Voit has electronic pressure monitors (shown here protected by green enclosures) installed on three presses, and will retrofit a fourth press this spring. The monitors gauge pressure to 14 nitrogen-gas springs installed at key stations in each press table.
“We intend to replace analog switches with electronic on all of the larger dies in which we run in-die welding operations,” says Pennington, who notes that the retrofit process is “simple and straightforward.”
In addition to less-frequent destructive testing and greater assurance that the in-die welding process is performing as designed, using the electronic nitrogen-pressure monitors has eased the troubleshooting process.
“Because the tolerance window was so large in the past, as well as the hysteresis, we’d waste a lot of time trying to pinpoint the exact cause of a shutdown. We would, for example, spend time adjusting welding parameters, leading to a long and tedious trial-and-error process that often was unnecessary. Now we can look at the digital readouts of the pressure monitors and know instantly if gas-spring pressure is the problem, or not, and address it immediately.”
Deep-Draw PPM Slashed from 300 to Zero
Tolerances on deep-drawn servo-motor and booster housings stamped at the Voit Automotive facility in El Salto, Jalisco, Mexico, average ±0.002-0.003 in. That level of precision requires state-of-the-art process control, says engineering manager Raphael Zazzaretta, which is why he’s sold on using electronic pressure monitors at critical nitrogen-gas-spring die locations. The plant has the Dadco electronic pressure monitors installed on three presses, and will retrofit a fourth press this spring.
“Other types of pressure switches might function as-designed,” says Zazzaretta, “but the electronic monitors are the state of the art. In particular, the ability to program the gauges for upper and lower setpoints makes a big difference in our ability to control our deep-drawing processes.”
Voit’s Jalisco plant operates six transfer presses and nine progressive-die presses, running 220 dies and 150 part numbers. Zazzaretta told us of one particularly challenging part where the addition of electronic pressure monitors had an immediate and measurable payback—stamping of booster-motor housings. The housings, of galvanized steel sheet, run in a 12-station blank-fed transfer die, where concentricity tolerances are ±0.1 mm. “Even the slightest bit of nitrogen leaking causes out-of-tolerance draws from the very first die station,” says Zazzaretta. “Or, the parts can become stuck in the die and cause transfer problems.”
Responsibility for in-die pressure control falls to a set of 14 nitrogen-gas springs installed in the press table, not the die. “This setup makes it easier for us to achieve the required level of precision compared to using a press cushion,” says Zazzaretta. Eight of the die’s 14 stations contain nitrogen springs. At the draw stations, the springs act as a cushion Each spring connects to an electronic pressure switch—14 separate switches connected to the nitrogen filling station.
“The pressure switches trigger a press shutdown only once every few months,” says Zazzaretta, “due to out-of-tolerance gas pressure to the springs. This may not seem like much, but when you don’t immediately see a problem in the press, it causes quality issues. This is particularly important with these housings, since their design makes it difficult for operators to visually identify tolerance issues—primarily varying wall thickness.”
Now, the firm no longer has to worry about nitrogen-gas pressure causing quality issues with this critical die. With part volumes approaching 3 million/yr., the die is running with a PPM of zero. This is a significant improvement compared to a PPM of 300 when the project first launched, without the electronic pressure monitors.Zazzaretta continues to tell us of his latest project involving the electronic pressure monitors—a press that will run several different part numbers and dies. “Here, we’ll include the settings for each pressure monitor in the part program, so that the PLC will automatically adjust the high- and low-pressure setpoints based on the die,” says Zazzaretta, “without operator intervention. The program will automatically instruct the nitrogen filling station to provide the required gas pressure to each spring as programmed.” MF
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