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Copy and Paste This Permanent Link:http://www.stormh2o.com/buyers-guide-2010/structural-stormwater-bmps.aspx

Photo: Utah DOT

The ongoing battle between stormwater professionals and stormwater runoff has spurred the creation of a wide range of structural best management practices (BMPs). From HDPE pipe to sophisticated filter systems, there’s a product for virtually every situation.

Many projects combine one BMP to treat the runoff and another to allow it to infiltrate. The following five projects highlight some of the best of the available methods and technologies.  

Legacy Parkway and Nature Preserve
Buried along a new 14-mile highway between Salt Lake City and Farmington, both in Utah, HDPE pipe is protecting valuable wetlands.

The Legacy Parkway, an alternate road between the two cities, opened in September 2008. It runs along the newly created 2,200-acre Legacy Nature Preserve on the southeastern shore of the Great Salt Lake. The preserve is part of the Pacific Flyway for migratory birds.

The preserve, established to help mitigate the impacts of the parkway on the wetlands and its wildlife, includes more than 700 acres of wetlands. It provides habitat for more than 100 bird species, including bald eagles, owls, peregrine falcons, shorebirds, and ducks.

“It’s nestled between a mountain range on the east and Great Salt Lake on the west,” says Rick Campagna, a project manager for the Utah Department of Transportation (UDOT) Legacy Project. “The parkway is in such close proximity to the lake, we were concerned about the wetlands. We wanted to design the project so it didn’t create a dam.”

UDOT used more than 65,000 feet of Advanced Drainage Systems (ADS) HDPE pipe and 400 feet of Hancor HDPE pipe, for more than 10 miles of pipe altogether.

“We were very meticulous about our approach,” says Campagna. “We delineated the wetlands within the project in an effort to save as much as we could. In the end, we managed to impact only about 80 acres.”

Although the parkway was very controversial among environmentalists and others, it ensured that the wetlands would survive. “The parkway drew a line in the sand, separating land that can be developed in the future, on the east side of the road, and land that has been set aside as the nature preserve, which will never be developed, on the west side,” he says.

And in some ways, the Legacy Project improved the wetlands. For example, one of the features UDOT took into account was the oxbows that had formed over the years in the Jordan River, which flows through the preserve and empties into the Great Salt Lake. Before the area began to be developed, floodwater from the river would fill the oxbows. But with development, the flow of the river was controlled and the oxbows dried out. The project has put water back into the oxbows again.

Drainage has been crucial in this project. Multiple culverts run under the parkway, allowing runoff from the mountains to the east and the lake to the west to drain under the road.

UDOT used multiple piping systems to handle the runoff from the mountains and the lake and multiple sizes of pipe to handle the different flows. Some of the natural channels in the preserve have fairly high flows and require pipes as large as 60 inches in diameter, Campagna says. Other areas, such as roadway drainage, have lower flows and require pipes as small as 18 inches.

Photo: Utah DOT Laying pipe in the trenches

Most of the pipe came from ADS, the world’s largest producer of HDPE corrugated plastic pipe, and was manufactured at a nearby plant. The 400 feet of 54-inch-diameter pipe is made by Hancor, which was founded in Findlay, OH. It is owned by ADS and operates manufacturing facilities and service centers across the country. Both ADS and Hancor pipes have an integral bell and spigot system, and Hancor pipes have a polymer composite fused to the outside of the bell with a factory-installed gasket.

UDOT chose these pipes, which have a corrugated exterior and a smooth interior, for a number of reasons. “From a long-term perspective, you don’t see the same kind of deterioration with HDPE as you do with corrugated metal piping,” says Campagna. “The soil tends to be corrosive because the lake floods in the spring. When it dries, it leaves a salt deposit.”

The pipes are watertight, lightweight, and cost-competitive. They can be handled with minimal equipment by a one- or two-person crew, even in 20-foot lengths. This length reduces the number of joints, saving labor and installation time.

“The pipes fit perfectly into our stormwater strategy,” he says. “It’s something we looked at very carefully. They’re improving the quality of the wetlands.”

Evanston Township High School
When Evanston Township High School in Evanston, IL, wanted to redo its athletic facilities and a city ordinance required it to install stormwater detention, the school took the idea and ran with it. The school selected a system that not only would detain most of the stormwater runoff from the site, but also would use the runoff to irrigate the school grounds.

“Any time we can intercept stormwater and recycle it through irrigation, it’s a plus,” says Kevin Camino, P.E., principal and a senior project manager at Eriksson Engineering Associates Ltd. in Grayslake, IL, which designed the project. “Sometimes the initial cost [of a reuse system] is more, but it will save on irrigation costs in the long run.”

Evanston, which is north of Chicago and along Lake Michigan, faces flooding during even moderate rainfall. Storm runoff, which discharges into a regional deep tunnel, can exceed the capacity of the sewer system, and water levels can rise enough to cause basement and street flooding. The city requires that the runoff rate after development not exceed the predevelopment rate, which is no more than 0.15 cubic feet per second (cfs) per acre.

An underground detention system, StormTrap, was installed at the high school in 2008. The concrete modular stormwater detention system, built by precasters throughout the country, was chosen because of its expected longevity and the determination that ultimately it was the most economically viable system available.

“Underground detention is typically more costly than aboveground detention, but it allows the land to be utilized more efficiently,” says Camino.

A city street divides the campus into the north side, which now has synthetic turf in the new soccer and football stadium, and the south side, which has natural turf in the new baseball, soccer, and softball fields. StormTrap was installed in both locations.

The project used the DoubleTrap system, which is watertight, to maximize the total water stored while minimizing the footprint of the system. The StormTrap system can also be configured to allow water to infiltrate into the soil and can include treatment options such as sand filters and sediment basins. The rectangular units that make up the system range in height from 2 feet 4 inches to 10 feet, allowing them to be configured to virtually any site.

Because the units used in this project are 10 feet high, crews excavated about 12 feet deep and placed aggregate bedding in the hole to create the StormTrap foundations. On the north side, they discovered soft clay subsoil.

Photo: Utah DOT The project used more than 65,000 feet of pipe from 18 inches to 60 inches in diameter.

“In general, the football stadium had really bad soils,” says Camino, “and synthetic turf requires a very firm base. We used lime stabilization to stabilize the clay before we installed the stone drainage layer.”

In the soccer and football stadium, the lime stabilization increased the impermeability and load-bearing capacity of the clay to form a “bridge” between the clay and the stone aggregate.

On the north side, crews installed 18 StormTrap units, which can handle 11,273 cubic feet of runoff. On the south side, 71 units can handle 55,075 cubic feet.

“The system collects the majority of the water that hits the school district’s fields,” says Camino. Runoff from both the north and south sides flows into catch basins, where it is routed through underdrains to the StormTrap units.

The runoff doesn’t have to be treated, he says. “Synthetic turf is cleaner than a parking lot, and with grass areas, you’re just talking about fertilizer.”

The stored water is pumped through a new, fully automated irrigation system to irrigate the grounds. The system is connected to the city’s water supply as well, so it can draw water for irrigation from the city when necessary. The school’s system provides 80 to 90% of its irrigation water, depending on the amount of rainfall.

Maintenance is minimal. StormTrap should be inspected once a year for sediment.

“It was a terrific project,” says Camino. “A lot of municipalities haven’t updated their ordinances to provide credit for stormwater detention or water-quality systems like these, so there’s little incentive to install them.” The city of Evanston has provided credit for both.

Woodcrest Project
When developers Miller & Smith built Woodcrest, a community of 81 housing units on 47 acres in Clarksburg, MD, they faced strict water-quality regulations.

“The site is on a special protection area; it’s very sensitive,” says Glenn Fritz, president of Deneau Construction in Gaithersburg, MD, which installed the development’s water treatment and infiltration system in 2008.

The community is in densely populated Montgomery County, MD, which requires post-development stormwater runoff from new development to equal predevelopment stormwater runoff conditions. The county also requires advanced filtration and groundwater recharge. In addition, Woodcrest is located next to the 3,700-acre Little Bennett Regional Park. Runoff drains into the Little Bennett and Seneca Creeks, and from there, into the environmentally sensitive Chesapeake Bay.

Brian Lewandowski of Gutschick, Little and Weber designed the system. Because the site had no room for typical recharge ponds, the treated runoff had to be stored underground. He used StormChambers from HydroLogic Solutions to control stormwater runoff and remove sediment and nutrients, as well as Contech Stormwater Solutions’ StormFilter, which removes oil and grease, dissolved heavy metals, herbicides, and pesticides.

StormChambers are made of HDPE and have an open bottom to allow water to recharge into the ground. When three models of the chambers—start, middle, and end—are placed in interconnecting rows, they capture stormwater, hold the solids, treat the water, and allow it to seep into the ground, recharging the groundwater and maintaining base flow to streams and wetlands.

Photo: Eriksson Engineering Installing the bottom units of the DoubleTrap system

“They’re basically the same thing as a septic system,” says Lewandowski. A biomat of microorganisms forms on the soil and stone under the chambers, metabolizing and converting pollutants and nutrients to noncontaminating byproducts.

StormChamber units also can be used instead of pipe to convey stormwater by placing the middle chambers end to end. “This is the first time we’ve put in StormChamber units,” says Fritz. “They were light and easy to install, and they didn’t require large equipment.”

Crews dug trenches, some of them up to 14 feet deep, and then lined the bottoms with aggregate topped with a geotextile netting. The netting allows water to infiltrate while preventing it from eroding the underlying stone and soil.

The crews then installed the start, middle, and end chambers as well as StormChamber SedimenTraps, units that catch sediment that runs into the chambers. The trenches were backfilled with more stone to 6 inches above the chambers, topped with nonwoven filter fabric, and backfilled with soil. Sediment that accumulates within the SedimenTraps is removed with a vacuum truck through a 10-inch riser pipe centered above the SedimenTrap.

About 75 units are installed in roughly 11 different locations at Woodcrest, Fritz says, all of them under green areas. Each unit is 34.04 inches high, 5 feet wide, and either 7.6 or 8.1 feet long, depending on the model, and can handle 10 cubic feet of water per linear foot. Each has a side portal that can accept up to a 12-inch inflow pipe and a top portal for clean out.

“Some StormChamber units catch runoff from roof drains and others from the streets after the water is treated,” says Fritz. Water from roof downspouts is sent directly to a StormChamber system. Water from the streets, which contains oil and heavy metals from cars, flows into storm drains to a StormFilter, which provides direct filtration. From there it goes to a StormChamber system.

Once inside a StormChamber system, water fills the interconnected chambers and the stone backfill. It slowly infiltrates through the open bottom of the chambers into stormwater trenches and, from there, down to the creeks.

Maintenance is simple. Crews usually just check once or twice a year to make sure the chambers aren’t holding water or sediments.

“We’ve put in similar products that have failed,” says Fritz. “We were very happy with these. They are huge water-quality retention systems, and residents don’t even know they’re there.”

Westside Water Quality Improvement Project
Runoff from two of the country’s best-known cities pollutes some of its best-known beaches. It flows through approximately 2,500 densely urban acres of Santa Monica and West Los Angeles, both in southern California, during droughts as well as rainstorms. It converges at the Sawtelle Flood Control Channel, flows into the Ballona Creek, and empties into Santa Monica Bay on the Pacific Ocean.

Photo: Eriksson Engineering Installing the top unit of the DoubleTrap system

Both the creek and the bay have total maximum daily loads (TMDLs), according to Neal Shapiro, urban runoff management coordinator for the City of Santa Monica and supervisor for the city’s Watershed Management Section of the Office of Sustainability and the Environment. Removing pollutants before they reach the bay is crucial to the health of Santa Monica and other Los Angeles beaches, the bay, and the waters beyond.

In 2006, Santa Monica, with the support of the county and the city of Los Angeles, completed the Westside Water Quality Improvement Project, which won the California Stormwater Quality Association’s (CASQA’s) 2007 Outstanding Stormwater BMP Implementation Project Award in the Treatment Control/Structural BMP Category.

“The issue addressed by this project is dry- and wet-weather runoff entering the Ballona Creek,” explains Shapiro.

He was in charge of recommending, organizing, documenting, and reporting the project, as well as getting it funded. The city hired an engineering consultant, Black & Veatch, to select the products that would best meet the city’s objectives for treatment, cost, and long-term performance. The company came up with Bio Clean Environmental Services’ Nutrient Separating Baffle Box and Contech Stormwater Solutions’ StormFilter.

To meet TMDL requirements for both the bay and the creek, the project diverts dry-weather and some wet-weather runoff from the Sawtelle Channel and treats it at Mar Vista Park, in the City of Los Angeles, before the runoff reaches the Ballona Creek. The goal is to treat all dry-weather flow up to 2 cfs, and in wet weather to remove up to 80% of suspended sediments and floatable trash larger than 1/8 inch in diameter—as well as other soluble pollutants such as heavy metals associated with sediment and trash—up to 33 cfs. Flows exceeding 33 cfs are not diverted. All treated water is returned to the Sawtelle Channel.

Photo: Eriksson Engineering Installing DoubleTrap, the modular water detention system at Evanston Township High School, Evanston, IL

Mar Vista Park wasn’t Santa Monica’s first choice. A number of locations in Santa Monica didn’t pan out for various reasons, but in many ways the park was perfect. The channel runs under the soccer field, and the park has adequate open space and no utility or traffic issues. However, a project to redo the soccer field was already planned.

“Once the soccer field was in, Santa Monica could not come back and put in the pipeline,” says Shapiro. “It had to go in with the LA project.”

The solution, which required negotiation and cooperation between the two cities, was to divide the project into two phases: phase 1, the installation of the diversion pipeline during the soccer field project, and phase 2, the installation of the treatment system after the soccer field project was completed.

Now that the project is completed, a 36-inch pipe diverts water from the channel to an adjustable weir, which is screened to remove trash and floatables, and a splitter box, which sends wet weather flow to the Baffle Box and dry weather flow to the StormFilter unit.

The Baffle Box can treat all of the wet-weather flow. It can capture and store thousands of pounds of trash, debris, and sediments, including hydrocarbons, nutrients, metals, and organic compounds attached to the former gross pollutants, according to Janet Kent, vice president of Bio Clean Environmental Services Inc.

Photo: City of Santa Monica Laying the diversion pipeline, which runs from the Sawtelle Channel to a treatment facility at Mar Vista Park

Sediment and water sink to the bottom of the box. The top is screened to capture trash and debris, which allows them to dry out between rain events and keeps the water from degrading further during storage, preventing nutrient leaching, bacterial growth, septic conditions, and bad odors. The screen also reduces maintenance costs, Kent says, because the material captured on the screen can be removed dry.

The StormFilter unit is screened and removes suspended particulates by sedimentation as well. It also provides direct filtration, removing oil and grease, dissolved heavy metals, herbicides, and pesticides.

According to Shapiro, “There is a minor issue in that often more dry-weather water is flowing into the splitter box, and the weir has to be raised slightly to retain all the dry-weather flow.” If the weir isn’t raised, some dry-weather flow can spill over and flow to the Baffle Box. While the Baffle Box provides screening and sedimentation, it doesn’t filter runoff for soluble pollutants.

Maintenance could have been a problem because the facilities belong to Santa Monica but are in Los Angeles. Fortunately, because of the cooperative relationship they established during the planning stages, the two cities have agreed that Santa Monica will maintain the facilities after providing Los Angeles with proper notification.

In 2007, the project reached its goal, according to Shapiro: “The Baffle Box had its first cleaning on November 15, 2007, in which 1,660 pounds of plastic take-out containers, aluminum cans, plastic bottles, plant material, and sediment were removed.” Although much less trash was found during the second cleaning, in February 2008, he speculates that there was less trash in the channel to begin with. Most of the rain events occurred before the first cleaning, which flushed out the built-up trash in the upstream pipes and channels from the previous summer and fall.

Photo: City of Olympia Excavation before the installation of the geogrid, two layers of aggregate, perforated pipe, and StormFilter

He says he is pleased with the way the Baffle Box is working. “It effectively removes trash, debris, and sediment.”

Decatur Street LID Roadway Project

Since the summer of 2008, two blocks of a suburban street in Olympia, WA, have been the site of a low-impact development (LID) demonstration project comparing different methods of cleaning and infiltrating stormwater.

“We were looking for ways to manage stormwater in the right of way,” says Craig Tosomeen, P.E., water resources engineer for the city’s department of Public Works. Tosomeen took the project from conception through construction and now does the monitoring.

The area is the headwater for Schneider Creek, which flows into Puget Sound, home to species of endangered salmon. The roadway was originally developed with no stormwater treatment and experienced minor flooding during rain events. Runoff from much of the neighborhood flows into the stormwater conveyance, which then flows into the creek.

Because no undeveloped land is available for aboveground detention and treatment, all three methods in the Decatur Street LID Roadway Project use under-the-road infiltration. They begin with Tensar Biaxial Geogrids within the drainage layers. One 200-foot section uses porous asphalt. Another uses traditional asphalt with rain gardens. The third uses traditional asphalt and
Contech’s StormFilters.

Photo: City of Olympia The finished project

Other StormFilter systems in the city have performed very well, Tosomeen says. They target total suspended solids (TSS), soluble heavy metals, oil and grease, and total nutrients. The geogrids, made of HDPE, stabilize the rock in the aggregate base and distribute the weight from the road surface, allowing the native subsoil to be disturbed as little as possible.

The water-quality goal of the three methods is to treat at least 91% of the stormwater that falls on these sections of road, according to Tosomeen. Each of the StormFilter units in this project is designed to accommodate 7.5 gallons per minute. The flow control goal of the project is to infiltrate all the stormwater that falls on the road sections. The design infiltration rate of the native soils is 0.15 inch per hour. This low infiltration rate is typical of Olympia’s fine-grained native soils.

The StormFilter system was very easy to install, says Rolland Ireland, engineering project inspector for Olympia’s department of Public Works. Crews excavated, then lay perforated pipe and 12 inches of aggregate over the subsoil. They covered the aggregate with the geogrid, an aggregate base course, and asphalt.

The biggest challenge was figuring out how to avoid disturbing the fiber-optic system that was already buried there, he says. “We went to design depth on the edge of the system, and came up and over.”

Photo: City of Olympia Top layer of aggregate

During a rain event, the road surface directs runoff into one of the StormFilters. Runoff flows through a filter cartridge and up the center tube into the collector manifold. When the filtered water reaches the top, it flows out of the system and into the perforated pipe. It trickles through the holes in the pipe into the aggregate and down into the subsoil.

StormFilter has a self-cleaning function that helps minimize maintenance. After a storm, the water level in the StormFilter drops, air rushes in, and sediment in the filter cartridge falls to the floor of the system, helping restore the filter’s permeability.

“We expect to change the filters yearly,” says Tosomeen.

In the fall of 2008, the city began a two-and-a-half year study to monitor TSS and dissolved metals and nutrients, as well as to look at infiltration. It’s too soon to have definite results for either type of pollutants, he says, but the StormFilter seems to be working well.

The area has had some very large storm events, and although the system didn’t infiltrate all the runoff, he isn’t worried. Success would be to replicate the hydrology of the native forest, he says, and there would have been some runoff in that predevelopment condition with that amount of rain.

As far as filtration, Tosomeen says, “The jury is still out, but anecdotally the filter seems to be the best way of cleaning the water. Visually, the clarity is very good.”