Corrugated polyethylene pipe (PE), which can be handled with minimal equipment by a one- or two-person crew, is providing a long, lightweight alternative to concrete pipe, according to its maker, Advanced Drainage Systems (ADS), Columbus, Ohio. The PE-pipe’s long “stick” length is designed to reduce the number of joints needed, which also saves labor and installation time. More than 33 miles of PE pipe, mostly 24- and 30-in. diam, is being used for the gravity storm drain system. I-15 general contractor Wasatch Constructors expects the PE pipe to save about 15%in materials, labor and time compared with concrete pipe.
The pipe being used is the ADS N-12 ProLink Ultra series with an integral bell and spigot to provide a secure gravity storm drain system.
“Because it is PE pipe, we don’t have to string it out along the trench like we do concrete,” said Marwan Farah, project roadway/design coordinator for I-15. “About a foot-and-a-half of granular fill is placed into the trench as pipe bedding. The granular fill depth depends on the amount of clay in the soil. The crew then lays pipe sections into the trench and ‘pops’ them together. A foot of fill is placed over the pipe and packed down. Then we totally backfill the trench. Usually, the trench is about 3 to 4 ft deep for the 24 in.-diam pipe, with some sections buried 14 to 15 ft deep below the sub-base.
“The trench is easily dug with a backhoe. The pipe’s even profile eliminated the need for additional ‘dig-outs’ to accommodate the bulging bell found on concrete and other PE pipe.”
The pipe has a neoprene gasket on the outer rim of the spigot end of the pipe to meet all soil-tight applications. It also meets AASHTO and ASTM specifications for “soil tight” and water exfiltration isn’t a concern, the maker said.
Tom King, ADS engineering vice president, explained, “Many storm sewer systems today use joints with performance levels measured by ASTM tests. Our N-12 ProLink Ultra joints, designed as soil-tight, comply with the more stringent performance tests.”
The pipe also features a smooth interior wall for maximum hydraulic flow and a corrugated exterior for strength.
Big project, little time
The I-15 Utah DOT (UDOT) project carries some staggering numbers. The $1.5 billion project will demolish and replace 17 miles of major interstate highway, including 144 bridges and overpasses. Two facts prompted this project, called the biggest design-build freeway job in North America. The 30-plus-year-old I-15, Salt Lake City’s main north-south route, had reached the end of its natural life span and had to be replaced. UDOT also decided that the route should be expanded to handle increased traffic volumes.
The new I-15 includes advanced traffic management system components that link 550 traffic signals, hundreds of traffic sensors, 130 video cameras to monitor traffic flow and three traffic control centers throughout the Salt Lake valley. It will carry traffic to skiing and other sports sites for the Winter Olympics in February 2002. But the project’s biggest challenge is its short time frame—4 1/2 years—which necessitates giving top priority to materials, construction methods and time-saving methods.
The job went to Wasatch Constructors, a consortium of contractors and design companies, led by Kiewit Construction, Granite Construction and Washington Construction.
Kiewit Construction, of Omaha, Neb., is one of the largest general contractors in the U.S. and builds more lane-miles of interstate highways than any other contractor.
Granite Construction, Watsonville, Calif. and Washington Construction, Boise, Idaho, share the highway and civil construction of I-15. Design is handled by Sverdup Civil, St. Louis, Mo., and DeLeuw, Cather, of Pasadena, Calif.
Starting out
UDOT’s first step was deciding to use the design-build method of construction.
The typical design, bid and build process would have taken eight or more years. Wasatch was given just four-and-a-half years. Still experimental in the U.S., the design-build process has designers and builders working together, with construction starting as the blueprints come off the drafting table.
The design-build concept got its start in commercial construction projects. This is the first time it has been used on such a massive civil engineering project. Farah explained how the materials selection and approval process worked. “We had teams that would rate products and design by points. For drainage, polyethylene pipe was the hands-down winner, providing the savings the I-15 rebuild needed.”
There is 33 miles of pipe on the project, Farah said, “and 155savings using PE pipe instead of concrete over 33 miles adds up quickly and becomes a significant number. An 80-ft run of polyethylene pipe requires about three joints,” Farah said, “while reinforcing concrete pipe (RCP) needs 10. Add that to the ease of handling PE pipe, the fast installation plus the security of the rubber-gasket seal and it was obvious that the ADS product was the choice. “You also have to string out concrete pipe before installation, doubling the risk of cracking the bell or spigot due to rehandling. It also takes more than just a single forklift to move a large diameter concrete section, again increasing chances for damage,” he added.
“The PE pipe is tough,” Farah said. “We can drop it 100 ft and nothing will happen to it. If the bell on a concrete pipe is hit, the joint is gone and we have to get a new section. Even metal pipe is easily dinged and that’s no good.”
When they selected the PE pipe, Wasatch also had to consider a contract stipulation that required it to maintain the roadway for 10 years.
“We certainly didn’t want to have to dig up the new road to replace drainage pipe,” said Donald Clark, P.E., roadway engineering oversight coordinator for UDOT.
The hydraulics provided by the pipe’s interior design will, Clark believes, minimize slit build-up.
“The ball and ‘O’ ring will prevent infiltration,” he said. “Metal pipe would certainly require a drag bucket be pulled through to clean it out and this could damage the pipe and the joints.”
Farah knew that virtually nothing would damage PE pipe. “I spent many years dealing with and overseeing the installation of PE-pipe drainage and leaching systems for mining operations and that is a much tougher environment on the pipe than salt.”
Wick drains fit I-15 criteria
Due to the extent of the soft compressible clays prevalent throughout the I-15 project and the amount of time allotted for completion, Mebra Drain vertical wick drains manufactured by the Nilex Corp., Englewood, Colo., were chosen for fast and economical consolidation.
According to the manufacturer, the use of wick drains provides up to 959consolidation in a time frame of several months, versus traditional long-term settlement process of straight pre-load which takes up to five years or more.
James M. Cramer, vice president of the Nilex Corp., told ROADS & BRIDGES, “The Nilex Corp. is supplying the entire quantity of wick drains. Approximately nine million lineal meters of wick drains are to be installed at a depth of 30 meters for the I-15 project.” Most of the soil conditions present at I-15 are soft, saturated, compressible marine clays in varying depths, interspersed with frequent layers of dense sands and stiff clays.
The wick drains are being installed 1.5 m apart in a triangle pattern. The company deployed equipment with a maximum pushing force and vibratory hammers where site conditions were severe. In many instances, holes were pre-drilled to facilitate installation of the wick drains.
To ensure fast mobilization from one location to another within the project, the company developed four wick drain installation rigs mounted of Cat 350L or Cat 245 excavators. These units can stand the installation leads up in the air unassisted and place them in the area to be wicked.
According the manufacturer, typical wick drain installation rates averaged around 4,000 m per day, per rig, with high production days at 12,000 m per rig. The initial results show consolidation rates within the design expectations.
Geogrids hold surcharge
Tensar Earth Technologies Inc., Atlanta, is also a player in the I-15 project for Wasatch Constructors. Tensar provided Wasatch with geogrids, sheet-type mechanical soil reinforcements, which are applied to strengthen embankment fills.
The geogrids have been applied in three types of embankment structures: (1) temporary vertical retaining walls, (2) temporary reinforced soil slopes and (3) permanent reinforced soil slopes. Three temporary vertical retaining walls and seven temporary reinforced soil slopes have been used to contain embankment surcharges and prevent their encroachment upon the roadway during construction. Ten permanent reinforced soil slopes have been used to eliminate some retaining walls. In these applications, conventional grade separations consisting of 2:1 (horizontal: vertical) slopes with small walls as their toes were replaced with 1.5:1 reinforced soil slopes. Contech Construction Products Inc., of Salt Lake City, furnished the geogrids. Geotechnical Design Services Inc., of West Jordan, Utah, designed the temporary vertical walls. -