Philadelphia Water Department Southwest Wastewater Treatment Plant

Facility Basic Information

Operating Authority

Philadelphia Water Department

Location

Philadelphia, PA

Design Capacity

194 MGD

Peak Hydraulic Capacity

300+ MGD

Population Served

~1.2 Million (Regional)

Receiving Water

Delaware River (Estuary Zone 4)

NPDES Permit

Read more4D-Printed Smart Materials For Water Treatment

PA0026671

Year Commissioned

1954 (Major Expansion 1980)

1. Introduction

The Southwest Water Pollution Control Plant (SWWP) is a critical component of the Philadelphia Water Department’s (PWD) wastewater infrastructure and serves as the centralized biosolids processing hub for the entire city. Located near the Philadelphia International Airport on the banks of the Delaware River, this facility is permitted for a hydraulic design capacity of 194 million gallons per day (MGD). While it provides advanced secondary treatment for wastewater generated in Southwest Philadelphia and portions of Delaware County, its operational significance is amplified by its role in processing sludge transferred from the city’s Northeast and Southeast treatment plants.

Commissioned originally in the mid-20th century and substantially expanded in 1980 to meet Clean Water Act standards, the SWWP has recently become a focal point for renewable energy generation and sustainable resource recovery. The facility integrates a 5.6 MW cogeneration plant and the innovative Biosolids Recycling Center, which converts waste into Class A biosolids pellets. As PWD implements its renowned “Green City, Clean Waters” program to manage combined sewer overflows (CSOs), the Southwest plant stands as a testament to the transition from conventional wastewater treatment to modern water resource recovery.

2. Facility Overview

A. Service Area & Coverage

The SWWP drainage district encompasses approximately 55 square miles, covering Southwest Philadelphia, West Philadelphia, and the southern sections of Center City. Additionally, the plant serves a substantial suburban population through interconnects with the Darby Creek Joint Authority and other Delaware County municipalities. The service area is characterized by a dense mixture of residential neighborhoods, heavy industrial zones, and the Philadelphia International Airport complex. The collection system serving the plant includes vast networks of combined sewers, requiring the facility to manage significant wet-weather flow variations.

B. Operational Capacity

The plant operates with a permitted annual average design flow of 194 MGD. During dry weather, the average daily flow typically ranges between 160 and 180 MGD. However, due to the combined sewer system, the facility is designed to handle peak hydraulic loads exceeding 300 MGD during storm events. Flows exceeding secondary treatment capacity may undergo primary treatment and disinfection before discharge, consistent with CSO operational protocols. The facility also manages the solids loading equivalent of the entire City of Philadelphia (approx. 2.3 million combined population equivalent) due to the inter-plant sludge transfer force mains.

C. Discharge & Compliance

Read moreA Comparison Between Aerobic And Anaerobic Wastewater Treatment Technology

Treated effluent is discharged into the Delaware River Estuary (Zone 4) via a submerged outfall. The Delaware River Basin Commission (DRBC) and Pennsylvania Department of Environmental Protection (PA DEP) strictly regulate this discharge. The estuary is currently the subject of intensified regulatory focus regarding dissolved oxygen levels and aquatic life propagation, driving potential future requirements for enhanced nutrient reduction.

3. Treatment Process

The Southwest Water Pollution Control Plant utilizes a high-rate biological treatment train designed to handle varying organic loads and industrial contributions. Uniquely, the plant features High-Purity Oxygen (HPO) activated sludge systems, allowing for a smaller footprint and higher treatment intensity compared to conventional air systems.

A. Preliminary Treatment

Influent wastewater enters the headworks where it passes through mechanically cleaned bar screens to remove large debris, rags, and plastics. Following screening, the flow is directed to aerated grit chambers where heavy inorganic materials (sand, gravel, coffee grounds) settle out. The removed grit and screenings are washed, compacted, and hauled off-site for landfill disposal. Efficient preliminary treatment is vital here to protect the downstream high-speed centrifuges and pumps used in the solids handling train.

B. Primary Treatment

Wastewater flows into rectangular primary sedimentation tanks equipped with chain-and-flight sludge collectors. Here, flow velocity is reduced to allow settleable organic solids to drop to the bottom (primary sludge) and fats, oils, and grease (FOG) to float to the surface. The primary sludge is pumped to gravity thickeners, while the clarified primary effluent proceeds to secondary treatment. The primary tanks are covered to facilitate odor control, with foul air extracted to chemical scrubbers.

C. Secondary Treatment (High-Purity Oxygen)

The core biological process at SWWP is a High-Purity Oxygen (HPO) activated sludge system. Unlike conventional aeration basins that blow ambient air into the water, HPO systems utilize covered reactors where pure oxygen (generated on-site via Cryogenic Air Separation or VPSA) is introduced. This maintains high dissolved oxygen concentrations, supporting a dense biomass capable of treating high organic loads rapidly.

• Reactors: Covered, multi-stage tanks prevent the escape of oxygen and volatile organic compounds (VOCs).
• Clarification: The mixed liquor flows to secondary clarifiers where the biological floc settles.
• RAS/WAS: Return Activated Sludge (RAS) is recycled to the head of the reactor, while Waste Activated Sludge (WAS) is sent to centrifuge thickening.

D. Disinfection

The secondary effluent is disinfected using sodium hypochlorite (liquid chlorine) to eliminate pathogenic bacteria. Following the necessary contact time in the chlorine contact tanks, the water undergoes dechlorination using sodium bisulfite. This step is critical to reduce total residual chlorine (TRC) to non-toxic levels before the water enters the Delaware River, protecting aquatic life in the estuary.

E. Solids Handling & Biosolids Processing

SWWP serves as the solids processing center for PWD. Sludge from the Northeast and Southeast plants is pumped via force mains to Southwest for centralized treatment.

• Thickening: Primary sludge is gravity thickened; WAS is thickened using centrifuges.
• Anaerobic Digestion: The combined thickened sludge is pumped into large egg-shaped or cylindrical anaerobic digesters. The mesophilic digestion process reduces volatile solids and generates methane-rich biogas.
• Dewatering: Digested sludge is dewatered using high-speed centrifuges to produce a “cake” with higher solids content.
• Thermal Drying (Biosolids Recycling Center): The dewatered cake is processed at the on-site Biosolids Recycling Center (operated by a private partner). The facility uses thermal drying technology to produce Class A biosolids pellets, which are marketed as fertilizer or soil amendment, achieving near 100% beneficial reuse.

4. Infrastructure & Facilities

A. Physical Plant

The SWWP occupies a substantial footprint adjacent to the Enterprise Avenue industrial corridor. The site is characterized by its large enclosed oxygen generation towers, the distinct anaerobic digesters, and the massive Biosolids Recycling Center building. Due to its location in a low-lying area near the river, flood protection and stormwater management infrastructure are critical components of the site layout.

B. Energy Systems & Cogeneration

PWD has positioned SWWP as a leader in energy recovery. The facility operates a 5.6 MW Cogeneration (Combined Heat and Power) Plant. This system utilizes the biogas produced during anaerobic digestion to fuel reciprocating engines.

• Electricity: The power generated offsets a significant percentage of the plant’s grid consumption.
• Heat Recovery: Waste heat from the engines is captured to heat the anaerobic digesters, maintaining the mesophilic process temperature without the need for auxiliary boilers.

C. Odor Control

Given the proximity to residential areas and the airport, odor control is a high priority. The plant utilizes extensive chemical wet scrubbers (typically multi-stage systems using caustic and hypochlorite) to treat air from the headworks, primary tanks, and solids handling buildings. The enclosed nature of the HPO reactors further aids in containing process odors.

5. Recent Upgrades & Major Projects

Biosolids Recycling Center (BRC) – ~$45 Million (Private Investment)

Timeline: Completed 2012-2013 (Operational)

This Public-Private Partnership (P3) with Synagro Technologies involved the construction of a state-of-the-art thermal drying facility located on the SWWP campus. This project replaced the composting operations and allows PWD to convert biosolids into Class A pellets.

• Drivers: Need for reliable, long-term biosolids management; diversion from landfills; production of a marketable product.
• Results: Processing capacity for all of Philadelphia’s wastewater sludge; production of “Philly Green” fertilizer; significant reduction in truck traffic compared to hauling wet cake.

Biogas Cogeneration Facility – ~$47.5 Million

Timeline: Commissioned circa 2011-2012; Ongoing optimization.

• Scope: Installation of 5.6 MW cogeneration engines, gas conditioning systems, and heat recovery loops.
• Funding: Utilizing ARRA (American Recovery and Reinvestment Act) stimulus funds and low-interest loans from PENNVEST (SRF).
• Results: The facility produces approximately 43 million kWh of electricity annually, covering over 40-50% of the plant’s electrical demand and reducing carbon footprint by over 20,000 tons annually.

Flood Resilience & Electrical Upgrades (2020-2025)

Budget: Part of multi-year CIP allocations

With the Delaware River tidal influence, PWD has invested in hardening electrical substations and raising critical equipment above projected flood elevations. This includes the replacement of aging switchgear and the installation of flood barriers around critical assets.

6. Regulatory Compliance & Environmental Performance

A. Permit Requirements

Operating under NPDES Permit No. PA0026671, the SWWP is subject to strict limits on Carbonaceous Biochemical Oxygen Demand (CBOD5), Total Suspended Solids (TSS), pH, and Fecal Coliform. The permit also includes monitoring requirements for nutrients (Nitrogen and Phosphorus), although tight numeric nutrient limits are currently evolving based on DRBC water quality modeling.

B. Environmental Stewardship

The SWWP plays a crucial role in the ecological health of the Delaware River. By maintaining high removal efficiencies for CBOD and TSS, the plant prevents oxygen depletion in the estuary. The facility’s beneficial reuse of biosolids (Class A pellets) closes the nutrient loop, returning phosphorus and nitrogen to the land rather than the river or landfills.

7. Operational Excellence

A. Staffing & Expertise

The facility is staffed 24/7 by a team of PA DEP certified wastewater operators, industrial mechanics, electricians, and instrumentation specialists. PWD maintains a robust training program to ensure staff are qualified to manage the complex HPO and cogeneration systems.

B. Technology & Optimization

The plant utilizes a comprehensive SCADA (Supervisory Control and Data Acquisition) system for real-time monitoring of flows, tank levels, dissolved oxygen, and gas production. The integration of the cogeneration plant into the SCADA network allows for automated load shedding and peak shaving strategies to manage energy costs.

8. Challenges & Future Planning

A. Aging Infrastructure

Like many urban facilities of its era, SWWP faces the challenge of aging concrete structures and mechanical conveyance systems. PWD’s Capital Improvement Plan includes systematic rehabilitation of the primary settling tanks and digestion complex to extend their service life.

B. Nutrient Management Regulations

The Delaware River Basin Commission is currently evaluating “aquatic life” uses for the estuary, which may result in stringent ammonia-nitrogen or total nitrogen limits. SWWP, designed primarily for carbon removal, would require significant and costly retrofits (potentially needing additional land or new technologies like membrane aerated biofilm reactors) to achieve high-level nitrogen removal.

C. Climate Change Adaptation

Future planning is heavily focused on climate resilience. Engineering assessments are underway to evaluate sea-level rise scenarios that could impact the gravity outfall hydraulics and site integrity. Future capital projects will prioritize flood-proofing and wet-weather capacity management.

9. Community & Regional Impact

The SWWP is an economic anchor, enabling residential and industrial growth in Philadelphia and Delaware County. Its operation is vital for the Philadelphia International Airport, ensuring sanitary services for millions of travelers. Through the “Green City, Clean Waters” initiative, the plant is part of a broader strategy that creates green jobs and improves neighborhood aesthetics through stormwater infrastructure, reducing the hydraulic burden on the treatment plant.

10. Technical Specifications Summary

11. Related Facilities

• Northeast Water Pollution Control Plant: Sends sludge to SWWP for processing.
• Southeast Water Pollution Control Plant: Sends sludge to SWWP for processing.
• Biosolids Recycling Center: The co-located thermal drying facility operated by Synagro.

12. FAQ Section

Technical Questions

1. What is the treatment capacity of SWWP?
The plant has a permitted annual average design capacity of 194 MGD, with peak wet weather handling capabilities exceeding 300 MGD.

2. Does SWWP use pure oxygen for aeration?
Yes, the facility utilizes a High-Purity Oxygen (HPO) activated sludge process, which differs from conventional aeration by using covered tanks and oxygen generation systems.

3. How is the biogas generated at SWWP utilized?
Biogas from the anaerobic digesters fuels a 5.6 MW cogeneration plant, providing electricity for plant operations and heat for the digestion process.

4. What is the “Biosolids Recycling Center”?
It is a facility located on the SWWP site, operated via a public-private partnership, that thermally dries dewatered sludge into Class A biosolids pellets for beneficial reuse as fertilizer.

Public Interest Questions

5. How does the plant control odors?
The plant uses chemical scrubbers to treat air from the headworks and primary tanks, and the biological reactors are covered to contain odors. The thermal drying facility also has dedicated advanced odor control systems.

6. Where does the treated water go?
After treatment and disinfection, the clean effluent is discharged into the Delaware River.

7. Is the plant affected by heavy rain?
Yes. Philadelphia has a combined sewer system. During heavy rain, flows increase significantly. The plant treats as much flow as possible, but extreme events can trigger Combined Sewer Overflows (CSOs) elsewhere in the system to prevent plant washout.