Military Reserve Center Preserved
Jim
Irey, vice president of Gap, PA–based Berner Construction Inc., has made a
construction career out of renovating US military bases. So, in 2005, when the
US Navy needed a shoreline stabilization system reconstructed at the venerable
Floyd Bennett Field Marine Corps Reserve Center on the southern tip of Brooklyn,
NY, his experience with a wide variety of base projects helped him to win the
bid. Scheduling work around Jamaica Bay’s tides and working in a wet environment
were important aspects of the tricky five-month project.
Jim,
a civil engineer, and Andrea Irey, a chemical engineer, founded Berner
Construction in 2002. They started the company to provide construction and
remediation services to largely support the ongoing effort of the federal
government to address the military bases affected by the US Department of
Defense’s base realignment and closure program. While Berner Construction was
diversifying its services from base renovations, the need for shoreline
stabilization at Floyd Bennett Field had become critical and Irey stepped back
into a familiar role.
Floyd
Bennett Field, New York City’s first municipal airport, was built in 1931 and
named in honor of naval aviator Floyd Bennett, pilot of the first flight over
the North Pole in 1926. It was constructed to divert the increasing volume of
air traffic to New York City away from Newark Airport, where most New York-bound
flights landed. By 1933, Floyd Bennett Field was the second busiest airport in
the country. It was the landing site for Howard Hughes and other famous aviators
who flew around the world in the 1930s, was conveyed to the US Navy in 1941, and
served as a major stateside air base during World War II.
 |
Photo: Berner Construction Inc.
The shoreline at the Floyd Bennet Field Marine Corps Reserve Center in Brooklyn, NY, recently required stabilization. A deteriorating steel wall (above) was replaced with a stone revetment wall (below). |
 |
Long
past its prime as a major military base, Floyd Bennett Field began showing its
age in recent years. An old steel sheet pile seawall along the shoreline had
deteriorated over the years to the point where it had partially collapsed.
Shoreline erosion had begun to occur as a result, causing some damage to a
reserve center parking lot. “The wall had deteriorated to the point where it was
falling in on its own weight; the Navy wanted to mitigate that,” Irey says. “The
seawall was made from steel sheeting that is three-eighths of an inch thick and
standing above the water line 15 or 20 feet high. Predominately, the job was
hazard mitigation.”
Berner
Construction was contracted by one of the Navy’s Environmental Military and
Construction contractors to provide labor, equipment, and supervision to replace
1,200 feet of revetment seawall. The company started work in June 2006. The
first task was to demolish the existing seawall. “Over time, holes rusted
through the wall and waves would come in and erode the shoreline,” notes Irey.
“They tried to bolster it with old blocks of concrete. During the reconstruction
effort, we pulled out the concrete blocks, regraded the shoreline, and rebuilt
the armor rock revetment wall.”
The
construction team first installed a silt fence for erosion control. Then wood,
asphalt, and concrete debris were removed from behind the existing sheet pile
wall. Removal of the existing concrete cap on the sheet pile wall followed
before the steel sheet pile wall was removed above the mud
line.
With
the existing structure removed, the team went to work on constructing a
front-sloping stone revetment seawall that would stabilize the shoreline for
many years in the future. The underwater base of the seawall was to be sloped to
break the wave action and prevent erosion. First, the existing side slope was
regraded. Then, nonwoven geotextile fabric was installed to the mud
line.
Installing
the fabric was arguably the most difficult aspect of a project that, overall,
required the team to schedule work around the tide in Jamaica Bay. “We changed
our start time almost every day to accommodate the tide schedule,” says Irey.
“If the low tide was at five o’clock in the morning, we might start at ten in
the morning to catch the low tide on the way back in the afternoon—that way, we
weren’t using lights.
“To
perform the rock placement, we followed the tide out and then back in again,” he
continues. “We divided the project in half; half of the project was in the water
and half wasn’t. The water level reached halfway up the slope during high tide.
On the days where we couldn’t work in the water, we’d work on the top of the
slope. If there was a full moon, there was a lower low tide and a higher high
tide, so you had to work faster.”
The
cross-section of the slope was 30 to 35 feet long, with a 3-foot delta. “We’d
put two grade stakes down—one at 25 feet down and one at 15 feet down—and we’d
grade to them,” notes Irey. A Topcon GTS-236W Electronic Total Station and
RL-H3C Rotating Laser were used to hold grade and then check the grade to make
sure that the slope was not overfilled or underfilled and, thus, uniform. “At
the end of the day, you’re an artist and you want your work to look good,” Irey
argues. “Periodically, about once every three days, we would put a guy in waders
and a life vest at low tide to check the grade from the water’s edge to be sure
that we were meeting the intent of the design.”
Berner
Construction’s total station was part of Topcon’s GTS-230W series, the first
electronic total stations with wireless operation. This design eliminates the
use of a cable from the data collector to the instrument. The total station was
primarily a quality-control tool that was used during and after material
placement. “We would check the subgrade before we placed the material, and then
we would check it periodically before we would place the stone,” says
Irey.
Irey
recalls how difficult it was to get the fabric into place. The excavator
operator weighed down the fabric with the first of three layers of rock, a
bedding material. “As they were placing the fabric, the operator would have a
bucket of fine crushed stone—the bedding material—to sprinkle on it to weigh it
down. He was working in conjunction with the laborers as they were putting the
fabric down. We worked in 25-foot sections, across the entire cross-section,
since that was about the distance we could get done in a tide
change.”
The
layer of crushed bedding material was 6 inches deep. The next layer was 3 feet
thick and consisted of two layers of granite armor rock. The first layer
consisted of material with a smaller particle size to provide a base for, and
fill gaps in, a second layer with a larger particle size.
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The
logistics of constructing the armor rock layer proved challenging as well. A
very large quantity of material was required for the new revetment wall. It was
delivered by barge and off-loaded at strategic locations along the seawall.
“Rock was barged in from a quarry just north of the city,” says Irey. A second
barge unloaded the rock from the first barge using a clamshell attachment. “The
issue was that it’s a big rock that requires a steel truck for hauling. The
likelihood of getting the quantities delivered at the time we needed it was not
that great, so bringing it in by barge was more
manageable.”
The
final stage of the project included constructing a new stormwater interceptor
trench along the top of the new armor rock revetment wall and repaving the
parking lot. By early November 2006, the project was complete, and the base was
protected from Jamaica Bay’s powerful wave action for at least another 80
years.
Author's Bio: Don Talend of Write Results, West Dundee, IL, specializes in construction trade media.
March-April 2009
Military Reserve Center Preserved
Photo: Berner Construction Inc.
The first task was removal of the steel sheet seawall, which had badly deteriorated.
Jim
Irey, vice president of Gap, PA–based Berner Construction Inc., has made a
construction career out of renovating US military bases. So, in 2005, when the
US Navy needed a shoreline stabilization system reconstructed at the venerable
Floyd Bennett Field Marine Corps Reserve Center on the southern tip of Brooklyn,
NY, his experience with a wide variety of base projects helped him to win the
bid. Scheduling work around Jamaica Bay’s tides and working in a wet environment
were important aspects of the tricky five-month project.
Jim,
a civil engineer, and Andrea Irey, a chemical engineer, founded Berner
Construction in 2002. They started the company to provide construction and
remediation services to largely support the ongoing effort of the federal
government to address the military bases affected by the US Department of
Defense’s base realignment and closure program. While Berner Construction was
diversifying its services from base renovations, the need for shoreline
stabilization at Floyd Bennett Field had become critical and Irey stepped back
into a familiar role.
Floyd
Bennett Field, New York City’s first municipal airport, was built in 1931 and
named in honor of naval aviator Floyd Bennett, pilot of the first flight over
the North Pole in 1926. It was constructed to divert the increasing volume of
air traffic to New York City away from Newark Airport, where most New York-bound
flights landed. By 1933, Floyd Bennett Field was the second busiest airport in
the country. It was the landing site for Howard Hughes and other famous aviators
who flew around the world in the 1930s, was conveyed to the US Navy in 1941, and
served as a major stateside air base during World War II.
|
Photo: Berner Construction Inc.
The shoreline at the Floyd Bennet Field Marine Corps Reserve Center in Brooklyn, NY, recently required stabilization. A deteriorating steel wall (above) was replaced with a stone revetment wall (below). |
|
Long
past its prime as a major military base, Floyd Bennett Field began showing its
age in recent years. An old steel sheet pile seawall along the shoreline had
deteriorated over the years to the point where it had partially collapsed.
Shoreline erosion had begun to occur as a result, causing some damage to a
reserve center parking lot. “The wall had deteriorated to the point where it was
falling in on its own weight; the Navy wanted to mitigate that,” Irey says. “The
seawall was made from steel sheeting that is three-eighths of an inch thick and
standing above the water line 15 or 20 feet high. Predominately, the job was
hazard mitigation.”
Berner
Construction was contracted by one of the Navy’s Environmental Military and
Construction contractors to provide labor, equipment, and supervision to replace
1,200 feet of revetment seawall. The company started work in June 2006. The
first task was to demolish the existing seawall. “Over time, holes rusted
through the wall and waves would come in and erode the shoreline,” notes Irey.
“They tried to bolster it with old blocks of concrete. During the reconstruction
effort, we pulled out the concrete blocks, regraded the shoreline, and rebuilt
the armor rock revetment wall.”
The
construction team first installed a silt fence for erosion control. Then wood,
asphalt, and concrete debris were removed from behind the existing sheet pile
wall. Removal of the existing concrete cap on the sheet pile wall followed
before the steel sheet pile wall was removed above the mud
line.
With
the existing structure removed, the team went to work on constructing a
front-sloping stone revetment seawall that would stabilize the shoreline for
many years in the future. The underwater base of the seawall was to be sloped to
break the wave action and prevent erosion. First, the existing side slope was
regraded. Then, nonwoven geotextile fabric was installed to the mud
line.
Installing
the fabric was arguably the most difficult aspect of a project that, overall,
required the team to schedule work around the tide in Jamaica Bay. “We changed
our start time almost every day to accommodate the tide schedule,” says Irey.
“If the low tide was at five o’clock in the morning, we might start at ten in
the morning to catch the low tide on the way back in the afternoon—that way, we
weren’t using lights.
“To
perform the rock placement, we followed the tide out and then back in again,” he
continues. “We divided the project in half; half of the project was in the water
and half wasn’t. The water level reached halfway up the slope during high tide.
On the days where we couldn’t work in the water, we’d work on the top of the
slope. If there was a full moon, there was a lower low tide and a higher high
tide, so you had to work faster.”
The
cross-section of the slope was 30 to 35 feet long, with a 3-foot delta. “We’d
put two grade stakes down—one at 25 feet down and one at 15 feet down—and we’d
grade to them,” notes Irey. A Topcon GTS-236W Electronic Total Station and
RL-H3C Rotating Laser were used to hold grade and then check the grade to make
sure that the slope was not overfilled or underfilled and, thus, uniform. “At
the end of the day, you’re an artist and you want your work to look good,” Irey
argues. “Periodically, about once every three days, we would put a guy in waders
and a life vest at low tide to check the grade from the water’s edge to be sure
that we were meeting the intent of the design.”
Berner
Construction’s total station was part of Topcon’s GTS-230W series, the first
electronic total stations with wireless operation. This design eliminates the
use of a cable from the data collector to the instrument. The total station was
primarily a quality-control tool that was used during and after material
placement. “We would check the subgrade before we placed the material, and then
we would check it periodically before we would place the stone,” says
Irey.
Irey
recalls how difficult it was to get the fabric into place. The excavator
operator weighed down the fabric with the first of three layers of rock, a
bedding material. “As they were placing the fabric, the operator would have a
bucket of fine crushed stone—the bedding material—to sprinkle on it to weigh it
down. He was working in conjunction with the laborers as they were putting the
fabric down. We worked in 25-foot sections, across the entire cross-section,
since that was about the distance we could get done in a tide
change.”
The
layer of crushed bedding material was 6 inches deep. The next layer was 3 feet
thick and consisted of two layers of granite armor rock. The first layer
consisted of material with a smaller particle size to provide a base for, and
fill gaps in, a second layer with a larger particle size.
The
logistics of constructing the armor rock layer proved challenging as well. A
very large quantity of material was required for the new revetment wall. It was
delivered by barge and off-loaded at strategic locations along the seawall.
“Rock was barged in from a quarry just north of the city,” says Irey. A second
barge unloaded the rock from the first barge using a clamshell attachment. “The
issue was that it’s a big rock that requires a steel truck for hauling. The
likelihood of getting the quantities delivered at the time we needed it was not
that great, so bringing it in by barge was more
manageable.”
The
final stage of the project included constructing a new stormwater interceptor
trench along the top of the new armor rock revetment wall and repaving the
parking lot. By early November 2006, the project was complete, and the base was
protected from Jamaica Bay’s powerful wave action for at least another 80
years.