Portland's first sewer was a covered wooden trough that ran down Southwest Montgomery Street from Fourth Avenue to the Willamette River. Built in 1864, this simple system collected sewage from homes and businesses and carried it directly to the river. Over the following years, the collection system grew. By 1883, the City had installed 15 miles of terra cotta pipe ranging in diameter from 9 to 18 inches. By 1933, larger pipes made of concrete or brick extended the system to 1,100 miles of pipe that conveyed sewage directly into the Willamette River and the Columbia Slough.
In the early 20th century, public concerns about water pollution and public health increased. Tests in 1927 showed that the Willamette flowing through Portland was severely polluted. By the mid-1930s, salmon fingerlings placed in the river died within 15 minutes. Pollution had robbed the river water of nearly all its oxygen. The untreated sewage also carried disease-causing bacteria and other contaminants into the river. Swimming was banned.
Citizens took action. More than 4,000 Portland schoolchildren held a rally outside City Hall in November 1938 to demand cleanup of the river. Later that year, Oregon voters initiated and passed the Water Purification and Prevention of Pollution Bill. A newly established State Sanitary Authority began to enact wastewater treatment requirements for both cities and industries.
Portland responded by building the Columbia Boulevard Wastewater Treatment Plant (CBWTP) and a new system of collection pipes and pump stations. The plant opened in 1952 and began discharging treated wastewater to the Columbia River. The result was a huge improvement in the Willamette's water quality.
Still, problems persisted. In 1967, Oregon Governor Tom McCall pledged stricter pollution laws and a cleaner Willamette. By 1968, the state regulated all single, identifiable sources of water pollution discharges. In 1972, state efforts were augmented by new federal requirements under the Clean Water Act, which set national wastewater treatment standards and established a permit system.
Portland's treatment system evolved over the years, responding to new requirements and making significant gains to reduce water pollution. In 1991, the City began taking action to control combined sewer overflows, or CSOs.
Much of Portland is served by a combined sewer system, which carries sewage and stormwater runoff in the same pipes. CSOs occur during rainy weather when large amounts of stormwater fill combined sewers to capacity causing overflows directly into the Willamette River. Among other measures, the city expanded capacity at the Columbia Boulevard Wastewater Treatment Plant to treat the mixture of stormwater and sewage.
The CSO program is one of ten actions identified in the City's Clean River Action Plan, a comprehensive approach to achieve long-lasting water quality improvements. The Clean River Plan addresses more than one problem at a time to help meet multiple regulatory requirements, such as the Clean Water Act and Endangered Species Act. The Columbia Boulevard Wastewater Treatment Plant plays an important role in this integrated effort. Using the best available technology, innovative approaches, and skilled staff members, it is integral to Portland's ongoing work to protect public health and the environment in the years ahead.
1952: Primary treatment facilities start operation
Construction of the CBWTP was a significant milestone for Portland. Until then, raw sewage, industrial discharges and agricultural waste emptied directly into the Columbia Slough and Willamette River. These waterways had become so dangerously polluted that they were unsafe for both people and fish.
Portland's citizens responded to the crisis by approving a $12 million bond issue to build a wastewater treatment plant that would help decrease pollution. The new facility demonstrated the city's commitment to a healthier future.
1969: Primary treatment system expanded and modernized
In 1969, the original primary treatment plant doubled in capacity, from 150 million gallons per day (mgd) to 300 mgd peak wet weather capacity. The expansion included adding screening capacity, four new primary clarifiers, replacing the grit removal system and adding sludge thickeners.
Other improvements included additions to the administration building and screenhouse and increasing the size of the influent pipe.
1970: Solids lagoon constructed
Soon after the primary treatment expansion, the City built sludge lagoons just north of the plant. The lagoons provide Portland with flexibility in its program to recycle the solids generated by wastewater treatment.
In 1978, Environmental Services removed some of the lagoon contents, reconfigured the internal dikes, and raised the perimeter dike. In 2001, a multi-year and multi-phase program began to rehabilitate the lagoons. The first phase was the addition of an internal dike that will allow renovation of half of the facility, while keeping the other half in operation.
1974: Secondary treatment process and sludge processing facilities added
Secondary treatment became the national technological standard for treatment facilities as a result of the Clean Water Act. Portland's response was to upgrade the CBWTP to begin secondary treatment in late 1974. The secondary treatment expansion doubled the area occupied by treatment facilities.
The expansion included adding a blower building and control room, eight aeration basins, eight secondary clarifiers, a 300 mgd effluent pump station, a second outfall pipeline, a solids processing building and sludge heat treatment and dewatering facilities.
1983: Anaerobic digesters expanded
Sludge processing was the focus of treatment plant improvements in the 1980s. The heat treatment system was replaced with four new anaerobic digesters in 1983. This tripled the plant's digester capacity. A third primary sludge gravity thickener was added with the new digesters.
1984: Compost facility constructed
Soon after, four belt presses replaced centrifuges as dewatering equipment. Then, in 1984, a 60-ton per day in-vessel biosolids composter was constructed. The composter produced a recycled landscaping product for local use until it ceased operation in 1999.
1991: Maintenance/Stores (Dodd) Building constructed
A series of projects in the early 1990's improved program efficiency and site safety. A maintenance/stores building was built in 1991 to modernize and consolidate mechanical maintenance facilities, warehouse and purchasing facilities, and offices for operations and maintenance staff.
1992: Chlorine containment building constructed
A chlorine containment building was added to contain the 90-ton rail cars that once delivered bulk chlorine to the site, to contain the chlorine dosing equipment, and to provide scrubbing for any releases of chlorine within the containment structure. In 2005, the Columbia Boulevard Wastewater Treatment began using sodium hypochlorite, a strong bleach, to disinfect wastewater, and the chlorine containment building is no longer used to contain chlorine.
1993: Sludge cake handling facilities added
New biosolids conveying and storage facilities were added as the city began to focus on its land application recycling program.
1994: Secondary treatment process upgraded
The secondary treatment system was upgraded to include more energy-efficient aeration equipment and the process was upgraded to include the latest process technologies.
1996: Replacement headworks facility completed
Since the mid-1990s, several important projects have been completed at the CBWTP. The projects represent both significant investments in the wastewater treatment system and a new way of doing business. One major project was replacement of preliminary treatment systems (screening and grit removal) and the addition of influent pumping in a new "headworks" facility.
The new Headworks features the latest wastewater equipment technology. The facility also benefitted from staff and citizen advisors. All treatment processes are automated and covered or contained. The Headworks features the latest in odor control technology. The building includes interpretive areas for the public and is surrounded by extensive landscaping and a water feature.
1999: Chlorination system expanded
The CBWTP chlorination system was expanded in 1999 in order to disinfect peak flows of up to 340 mgd.
2000: Columbia Slough Big Pipe completed
Much of Portland is served by a combined sewer system, which mixes sewage and stormwater runoff in the same pipes. Combined sewer pipes once had sufficient capacity to carry the combined flow to the treatment plant. But as the City grew, increased volumes of wastewater and stormwater exceeded the system's capacity, resulting in combined sewer overflows (CSOs) to the Willamette River and Columbia Slough. Since 1991, Portland has built several CSO abatement projects to divert stormwater runoff from the combined sewer system and to expand sewage conveyance and treatment facilities.
The Columbia Slough Big Pipe, a 3.5-mile, 12-foot-diameter pipeline, was completed in 2000. The Big Pipe is the centerpiece of the Columbia Slough CSO program. It carries about 350 million gallons of sewage mixed with stormwater to the CBWTP each year. Before the Big Pipe was built, sewage overflowed directly into the Columbia Slough during rainy weather.
2000: Influent pump station constructed
Environmental Services built an influent pump station to pump sewage from the Big Pipe into the CBWTP. The facility has a peak capacity of 105 mgd. Together, the Columbia Slough CSO projects reduced CSOs to the Slough by 99%.
2000: New dry weather primary clarifiers added
The treatment plant has expanded to accommodate wet weather flow from both theColumbia Slough basin and the Willamette River basin. New dry weather primary clarifiers were added to replace the original 1952 facilities. The new clarifiers are covered and equipped with odor control.
2000: Wet weather primary clarifiers modified
The old primary clarifiers were converted to wet weather use. Completing a new wet weather outfall system to the Columbia River and adding a dechlorination facility on Hayden Island complemented the on-site wet weather improvements.
2006: Wet weather capacity improvements
The plant expanded the influent pump station and improved the influent channel.
2006: Plant effluent pumping improvements
This project increased pumping capacity to 450 million gallons per day (MDG).
2008: Dry weather clarifier addition
The plant constructed a fourth primary (dry weather) clarifier.
2011: Digester Expansion
The plant constructed digesters 9 and 10 to accommodate increased wastewater flow.
2011: Wet weather screening facility
This facility added an additional 150 million gallons per day of screening capacity to our Wet Weather Primary Treatment system.
2012: Chemically Enhanced Primary Treatment (CEPT)
The Chemically Enhanced Primary Treatment (CEPT) facility for wet weather wastewater flows adds ferric chloride and polymer to wastewater to make solid particles clump and settle faster and improve treatment plant efficiency.
2012: Secondary Process Improvement (SPI)
Using computer optimized plug flow control along with adjustable air diffusers for different parts of the aeration basins to increase sludge holding capacity and increase treatment efficiency during peak flows. Pilot programs indicated up to 25% increase in volume treated without solid loss.
2013: Portsmouth Odor Control Facility
The system uses live bacteria living on moistened bark chips to strip odors from the large Portsmouth tunnel before wastewater from the tunnel enters the treatment plant.
The Columbia Boulevard Wastewater Treatment Plant covers approximately 140 acres and is part of Portland's extensive wastewater collection and treatment system. The plant serves 614,000 residential and commercial customers. Wastewater is transported to the treatment plants through a network of more than 2,256 miles of pipes that range in diameter from 4 to 144 inches. Some pipes carry wastewater only (the sanitary sewer system), while others carry a combination of wastewater and stormwater (the combined sewer system sewer system). About 96 pump stations help move the flow along when gravity alone is not sufficient.