4th CES EOD employ new 3-D printing capability
By Airman Shawna L. Keyes
4th Fighter Wing Public Affairs
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Senior Airman Nathanael Banden, 4th Civil Engineer Squadron explosive ordnance disposal technician, checks on the 3-D printer as it prints a training aid, Dec. 14, 2016, at Seymour Johnson Air Force Base, North Carolina. Printing jobs can take anywhere from 10 to more than 48 hours to complete, depending on the size and complexity of the training aid. (U.S. Air Force photo by Airman Shawna L. Keyes)
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The 4th Civil Engineer Squadron Explosive Ordnance Disposal unit’s 3-D printer puts down plastic in layers to create glow-in-the-dark location markers, Dec. 14, 2016, at Seymour Johnson Air Force Base, North Carolina. The EOD flight utilizes the 3-D printer to create training aids that are approximately 90 percent less expensive than buying the real thing. (U.S. Air Force photo by Airman Shawna L. Keyes)
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Senior Airman Nathanael Banden, 4th Civil Engineer Squadron explosive ordnance disposal technician, compares a M904 Bomb Nose Fuze to its 3-D printed counterpart, Dec. 14, 2016, at Seymour Johnson Air Force Base, North Carolina. With the ability to produce training aids using inexpensive plastic materials, EOD technicians can cut, shear, puncture or completely obliterate a training munition to fully complete an exercise without financial repercussions. (U.S. Air Force photo by Airman Shawna L. Keyes)
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Explosive ordnance training aids sit in a display case at the 4th Civil Engineer Squadron Explosive Ordnance Disposal flight, Dec. 14, 2016, at Seymour Johnson Air Force Base, North Carolina. The EOD flight utilizes a 3-D printer to create plastic models of real training aids to be used in training exercises. (U.S. Air Force photo by Airman Shawna L. Keyes)
SEYMOUR JOHNSON AIR FORCE BASE, N.C., Jan. 17, 2017 —
In 2014, the Joint Explosive Ordnance Disposal community identified the need for a unit-level additive manufacturing, or 3-D printing, capability in order to accomplish two objectives: to field low-cost training aids and to obtain rare or specialized EOD tools.
In June 2016, the 4th Civil Engineer Squadron EOD flight became one of the first units U.S. Air Force-wide to acquire a 3-D printer and begin to pave the way for the career field’s next generation of training.
“There’s a lot of benefit to being able to produce items for training,” said Senior Airman Nathanael Banden, 4th CES EOD technician. “In addition to providing opportunities for more realistic training as the library of available [models] expands, our technicians will have access to items that they may have only been able to see in pictures or a glass case somewhere due to rarity or expense.”
With the use of 3-D printing, items that once may have only been available to specific EOD units can now be made available to those units that have procured their own 3-D printer. According to Master Sgt. John Moore, Air Force Civil Engineer Center Joint EOD equipment management section chief, there is an average decrease in cost of more than 90 percent between purchasing training aids and printing them. For example, the cost per unit of a 60 millimeter mortar is more than $700, whereas the cost to print a replica of this item is less than $6. It would also eliminate any shipping charges as the items could be created in-house.
“With 3-D printing, the unit can rapidly manufacture a minimal amount of operational tools, and as the stock dwindles, simply replace them,” said Moore. “With the ease of fabrication, they will also be able to exercise more of their more destructive procedures on these training aids without worrying how they will be replaced. All they need to do is print more. This creates a much more realistic training experience.”
Several new tools are currently under development at the Air Force Civil Engineer Center EOD Technology Division, in Indian Head, Maryland, to capitalize on this technology, added Banden. These advancements include linear water cutters, a hemispherical water charge and a speed cap which can convert almost any commercial water bottle into a disruption tool.
“When we deploy downrange, we’re possibly going to be exposed to weapons systems we’ve never seen before,” said Banden. “Having things in-house that we can train on beforehand [gives us the confidence] to say, ‘I know exactly what I’m supposed to do to make that item safer or to work around it safely. I’ve seen it before, I’m confident, let’s move ahead.’ Repetition builds a lot of knowledge and confidence in what you’re doing, which is critical, especially in the mission downrange.”
Banden explained that EOD training currently involves a certain level of artificiality. EOD technicians often have to terminate exercises before they are able to employ many of their more destructive procedures in order to avoid damaging expensive or irreplaceable training aids. With the ability to instead produce these aids using inexpensive plastic materials, EOD technicians can cut, shear, puncture or completely obliterate a training munition to fully complete an exercise.
In addition to training aids, certain items like the speed cap can be utilized downrange as a part of a standard deployment kit.
“Hopefully in the future downrange units will have 3-D printers,” said Banden. “If we run out of something that we have in our deployment kits, we can just print more without having to ship it over from stateside and wait for it. Or, say my radio bracket snapped and I really have to have that radio, I can simply print a new bracket. Simple things like that save time and lives.”
Banden further explained that 3-D printing has the potential to displace huge portions of the logistics process across the entire Air Force, not just within the EOD career field. As the ability to print with more unusual materials matures and becomes more cost effective there maybe unforeseen uses for the 3-D printer in the future such as replacement parts for damaged robots or vehicles; reducing cost and mission down time.
Editor's note: The original story can be viewed on the Seymour Johnson Air Force Base website.