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MC Magazine |
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Precast Under Live Fire
An Iraqi village mock-up in the California desert
provides U.S. Marines with the close-quarters training they'll
need in actual combat.
By Fernando Pagés Ruiz
Fernando Pagés Ruiz is a freelance
writer who covers business and industry news.
The U.S. Marine Corps Training Command Center
at Twentynine Palms functions as the largest Marine Corps
base in the world, covering a half-million acres of Southern
California desert. Maj. Richard Doherty oversees the integration
of new engineering systems for troop training, where the emphasis
has shifted to design facilities for military operations on
urban terrain (MOUT). “The war on terrorism unfolds
in cities and towns,” Doherty said. “As more people
move into urban centers, the world’s conflicts move
into dense, populated environments.” More than military
might, urban warfare requires experience in close-quarters
combat and highly trained light forces to move from street
to street and room to room, as well as the ability to distinguish
between civilians and hostile forces.
Reconstructing an urban setting for military
exercises might seem easy enough. But when it comes to live-fire
training, rounds from deadly M-16s and AK-47s can fragment
building materials and ricochet, creating a lethal salvo that
makes live-fire training difficult to engineer. Until recently,
soldiers have trained in urban settings primarily with laser
rifles and paintball guns. A revolutionary precast concrete
product now makes it possible for soldiers to conduct this
type of training with live ammunition.
“Soldiers need live-fire training
because paint balls and lasers do not replicate the emotional
experience of a loaded gun,” Doherty said.
Nevertheless, concerns with “surface
danger zones have hampered live-fire training in urban-like
environments,” he said. “But now we have the means
to safely prepare soldiers for battle.” The means comes
with a precast shock-absorbing concrete, which absorbs and
retains ammunition, eliminating the risk of ricochet or flying
debris.
Creating ammunition-absorbing
concrete
Jim Sigurdson was working as a consultant to the chemical
industry when a friend told him about early experiments to
produce bullet-absorbing concrete. Twenty years before, the
Army Corps of Engineers began development on a concrete that
could withstand live fire without fragmenting. Although research
stopped before developing a viable product, Sigurdson decided
to pursue the idea.
“I suggested we contact the Corps
and see if they might still be interested in developing this
concrete,” Sigurdson said. And they were. Two years
later, Sigurdson’s startup, Ballistics Technology, shared
a U.S. patent with the Corps for a revolutionary new precast
shock-absorbing concrete, a low-density, fiber-reinforced,
foamed concrete for use in the construction of urban-style
live-fire training facilities.
A new precast concrete
product
Precisely engineered to a density of 90 pounds per cubic foot,
bullet-absorbing concrete soaks up the kinetic energy of projectiles
in a controlled fashion without cracking or splitting the
product. The material allows bullets to penetrate without
ricocheting and then holds the munitions, providing a safe
live-fire environment and an ecological medium for handling
the lead. Encased in the concrete, the military can dispose
of spent rounds in a landfill just as it would dispose of
ordinary garbage.
Each batch mix must achieve certain density
requirements calibrated for specific munitions. “While
most concrete specifications require a minimum strength, such
as 4,000 psi, we work in absolute densities, measuring the
gravity of cement and sand as accurately as possible,”
Sigurdson said. In terms of strength, the shock-absorbing
concrete averages between 1,000 and 1,500 psi, but the mix
demands more than specific strength – it requires almost
perfect uniformity so that bullets can penetrate the concrete
at any angle up to 130 degrees without ricochet. To achieve
uniformity, the concrete is a mix of cement, selected aggregate
and fiber along with special chemical additives. The resulting
mix has very different working characteristics than standard
concrete.
When Ballistics Technology International
won a contract to construct two of the world’s largest
mockup villages for MOUT training, Sigurdson knew he had to
work with a precast manufacturer equipped to handle rigorous
quality control and develop a new casting process. Building
the first two five-acre Middle Eastern-style villages involved
2,200 wall panels, structural floor and roof panels, and specialty
pieces quickly erected in the Mojave Desert – 50 miles
from the nearest source of water. Sigurdson found the experience
necessary in Mid-State Precast LP and Pankow Special Projects
LP. Ballistics Technology manufactures the SACON precast concrete
components in a plant in Wilson, N.C. The firm enlisted Mid-State
Precast as a contract manufacturer. They joined to produce
the products on a large scale and to build the most advanced
live-fire training facility ever constructed. Pankow Special
Projects managed the site preparation and the product installation.
Application challenges
precast producer
As the plant superintendent for Mid-State Precast in Corcoran,
Calif., Matt Burden is no stranger to highly engineered precast
concrete applications. Mid-State has supplied precast concrete
for specially reinforced buildings in seismic zones and experimental
bridge pier components incorporating ductile, fiber-reinforced
concrete. But he had to rethink everything when it came to
shock-absorbing concrete. “Nobody had ever tried anything
like this at such a large scale,” Burden said.
“We had to come up with a method to
mix and pour this sticky blend of sand, cement, admixtures
and fiber that resembled dough more than concrete. In fact,
we used a planetary concrete mixer, a 10-foot diameter drum
with paddles that churned the stuff like a cake mixer,”
Burden said.
Since the concrete mix did not pour down
a chute like regular concrete, workers had to shovel it into
the ready-mix truck for transport to the foaming station.
Foaming is the key step in creating shock-absorbing concrete.
At the foaming station, a concentrated foaming agent was mixed
with water and pumped through hoses into the ready-mixed concrete
truck “at a consistency like shaving cream,” Burden
said.
A complex set of mathematical equations
determined the amount of foam required, achieving a precise
density of 90 pounds per cubic foot – much lower than
the standard 145 to 150 pounds per cubic feet for concrete.
But the challenges did not end with the
complex chemistry. After achieving the perfect mix, placing
the gooey substance into conventional molds, removing the
delicate pieces once cast and then curing them presented even
bigger hurdles.
“We had to cast 70 molds a day to
keep up with production,” Burden said. Since the mix
did not flow out of the truck on a chute and into the molds
as in standard pours, workers struggled to spoon the concrete
out of the trucks and into the molds without disturbing the
uniform blend. Because of its high viscosity, the concrete
did not self-level. Workers had to spread and then strike
the concrete level very carefully. “We couldn’t
use any standard vibration devices at all,” Burden said.
Instead, workers “rodded” the concrete by hand,
essentially poking it with shovel handles to achieve even
uniformity. “We couldn’t trowel the finish either,
which would create a slick, hard surface that could burst
off when fired upon,” Burden said.
The shock-absorbing concrete contains no
aggregates or steel reinforcement that might cause a bullet
to ricochet. The manufacturer could not extract the hardened
concrete pieces from their molds using conventional methods.
“We ended up adapting a high-pressure vacuum device
used in plate steel manufacturing to suction the pieces and
extract them,” Burdon said. Since the suction cups designed
for lifting steel could not easily form a vacuum in rough
concrete, Burden used a film of water to complete the seal.
“Since then we’ve found this vacuum device useful
in many other applications,” Burden said.
After fabrication, the pieces underwent
a rigorous wet-curing process. Within 15 minutes of releasing
each piece from its mold, workers applied a coat of water
and wrapped the piece in polyethylene sheathing. Once a full
cure was obtained, tests determined whether the rigorous manufacturing
process had produced the desired strength and density –
no less and no more. The pieces that passed this final exam
were loaded using foam-padded forklifts onto flatbed trucks
and shipped out to the desert.
Meeting the deadline
means more than the money
Tom Krajewski, group manager for Pankow Special Projects in
Oakland, Calif., had the job to erect 2,200 precast shock-
absorbing concrete panels for two MOUT training villages approximately
50 miles apart in the California desert. Marines would train
in rapid assault and street-to-street fighting tactics in
these installations. “These guys have to experience
the adrenaline of danger, the sounds and smell of live fire
before encountering it in the battlefield,” Krajewski
said. Live- fire training represents the final and most critical
stage of a soldier’s preparation. In this case, the
urgency to build this project quickly had a compelling element.
“Every project we do has a tight schedule,
and some have liquidated damages if the deadline is missed,
but this time it meant a lot more. The major told us that
every day we were not done, soldiers were dying for not having
the proper training,” Krajewski said. “That motivated
us more than any monetary concern ever could.”
Built to resemble Iraqi neighbor-hoods,
the two villages included an installation of 14 buildings
with a central plaza that Marines would use for convoy training
and a dense, 28-building village where Marines could practice
dismounts from helicopters and Humvees. Here Marines learn
how to move from one building to another avoiding sniper fire
and how to clear rooms, traverse hallways and communicate
in the heat of battle.
Using satellite photographs and the recollection
of experienced Marines returning from Operation Iraqi Freedom,
the Pankow group helped design the layout of the two villages
for safe and practical training while keeping true to the
typical village setting. Because the precast concrete panels
came in modular, interlocking 8-foot “T” shapes
about 40 inches across and 30 inches deep, the construction
proceeded quickly.
Pankow erected the panels over a granular
bed as a footing. The interlocking “T” shapes
prevented bullets from passing through construction joints.
Since mechanized targets pop up at window and door locations,
these riddled with bullets quickly. “In time when an
area becomes riddled with rounds, the area is cut out with
a carborundum blade and chipped out, then a precast concrete
block gets siliconed in place to fill the void. No loss of
structural integrity, and no worry of having to always move
targets,” Krajewski said.
When the Marines saw the need for two-story
buildings, Mid-State Precast had to develop a system to incorporate
standard precast concrete structural planks with the shock-absorbing
concrete. The precaster created a sandwich covering a structural
plank with shock-absorbing concrete. To protect the edges,
Ballistics Technology developed and cast edge blocks, which
also served as parapets and other architectural features.
Now, if an errant shot hits the ceiling or floor, no threat
of ricochet exists.
In the end, despite unseasonable rainstorms,
the unnerving effect of working while bombs detonate in the
distance and the challenges of building something no one has
ever constructed before, Krajewski and his crews delivered
the project on time and much to the Marines’ satisfaction.
Currently, Marines train in this state-of-the-art live-fire
facility made possible by American ingenuity and the highly
controlled, reliable performance of precast concrete.
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