WERF Research Report

Approximately 35% of a wastewater treatment facilities' total cost to provide wastewater service is for energy use. Industry wide, about 0.6% of the electric energy produced in the United States is consumed by commercial sector wastewater treatment. Clearly, the wastewater sector and other wastewater treatment providers, such as industry and commercial establishments, need cost-effective solutions for energy management and efficiency in their wastewater treatment operations. The interrelated problems of rising energy costs and demand alongside climate change have brought the issue of energy efficiency into the forefront of most every wastewater treatment provider today. The Operations Optimization Challenge is the Water Environment Research Foundation's (WERF) program to build integrated, comprehensive, long-term research into process optimization, energy efficiency, energy and resource recovery, and minimization of the environmental footprint of wastewater collections and treatment.


The primary goal of the Optimization Challenge is to develop approaches that allow the wastewater sector to attain a 20% or greater reduction in energy to achieve treatment goals. One of the goals of the Operations Optimization Challenge is to identify the approaches used by the most effective power utility or state energy efficiency programs. Using these most effective elements of these programs build upon success and promote energy efficiency at the facility by putting in place the framework for effective energy management at a higher level. Currently only four states have effective energy reduction programs with a long-term history of performance. This report is aimed at increasing the number of states or other agencies (interstate agencies as well as power providers) who can implement successful programs to assist the wastewater sector reduce nationwide energy demand.



In support of this goal, this report:

• Provides suggested language for incorporating energy efficiency related concepts in design guidelines or standards.
• Evaluates the feasibility of establishing a national design standard for wastewater treatment facilities which incorporates energy efficiency related concepts in an outlined model standard. This includes results from a technical working session of selected wastewater regulatory and energy regulatory agencies that was focused on the issue of incorporating energy guidelines in their respective standards.
• Identifies reviews and analyzes successful state and utility sponsored wastewater-related energy programs and suggests a model framework based on the key elements of these programs.

Available as an eBook only.


Value engineering is a technique that wastewater treatment facilities (WWTFs) currently use, when required, to analyze cost reduction and performance optimization opportunities. The research explores the potential to address energy efficiency during value engineering analyses of WWTFs. The research identifies the Society of American Value Engineers (SAVE) International as the primary value engineering standards and certification organization and shows the six-step SAVE process for conducting value engineering analyses. A survey of WWTFs identifies four WWTFs that conduct value engineering analyses using the SAVE process. Then, the research reviews the analyses to determine their effectiveness in addressing process energy efficiency opportunities. While the SAVE value engineering process does not require identification of energy efficiency opportunities, the analyses conducted by the WWTFs do identify such opportunities.



Based on survey results, WWTFs only conduct value engineering analyses when required, primarily because of the cost and time commitment. The research presents barriers to conducting value engineering analyses and discusses possible mitigation pathways. Pathways include (1) steps the State Revolving Fund can take, (2) development of a national value engineering standard that regulatory agencies can incorporate into wastewater system design requirements, and (3) development of WWTF-oriented energy efficiency training materials to add to SAVE's value engineer certification training.

Successful deployment of energy efficiency initiatives may be increased by recognizing barriers and advancing strategies that overcome them. A national survey recently collected input on barriers from more than 110 wastewater service utilities. A concurrent utility focus group process captured detailed experiences. Motivation is a crucial precondition for energy efficiency. The utilities reported that the strongest motivators for utility staff are reductions in energy expenditures and prioritization by utility management.

The project identified the following key barriers:

* Capital projects. Economic barriers dominate: inadequate financial feasibility, lack of funding, and resource competition with other organizational priorities.

* Operations optimization. Operational conservatism (desire for a margin of safety for permit compliance) is the strongest barrier to implementing operating changes that conserve energy.

* Maintenance for energy efficiency. Many utilities have not optimized maintenance intervals for energy efficiency because they prioritize more pressing maintenance activities.

The barriers considered by this research include both internal and external challenges. Internal challenges are mitigated by well-developed energy programs, as gauged by the level of implementation of the approaches outlined in the WEF Energy Roadmap. Utilities with well-developed programs perceive barriers as being lower. External challenges are reduced for water resource recovery facilities (WRRFs) in states with well-funded and accessible energy incentive programs and less-inhibitive energy policies.

The primary goal of the Optimization Challenge is to develop an approach that will allow the wastewater sector to achieve treatment goals while reducing the resources expended by 20% or more. The greater energy and chemical demands of facilities that provide nutrient removal make them a particularly challenging target, yet one with a significant potential return. This report has three objectives:

To evaluate the European Experience with energy reduction and best practices at wastewater treatment plants (WWTPs).
To evaluate the best practices employed at a European WWTP exhibiting significant energy reductions and energy management.
To develop a viable template for a mass and energy balance model to be used as the basis for a subscriber-accessible tool that will be developed later.
The project team considered European facilities that have a history of process optimization and could serve as examples of best practices for the industry. One of these is the Strass im Zillertal WWTP near Innsbruck, Austria, a municipal facility that provides for both nitrogen and phosphorus removal. A lengthy optimization process spanning more than a decade has enabled the Strass plant to attain the singular goal of producing more electricity on an annual basis than it consumes.

Factors specific to the plant contributed to the Strass WWTP's transformation into a net electricity producer, including the facility's need for only low level (5 meter static head) influent pumping. However, the bulk of the energy and process optimization resulted from a combination of national programs, concerted efforts by a highly-educated operations team, and an energy-conscious mindset. WERF and its subscribers can readily apply these success factors to North American facilities.

This study examined the context, drivers, and decisions behind the Strass WWTP enhancements toward energy self-sufficiency. These included:

Examining regional and national energy and resource conservation programs that target wastewater treatment facilities in Scandinavia, Holland, Germany, Switzerland, and Austria.
Assessing Energy Conservation manuals used to promote resource conservation in European WWTPs.
Defining metrics applicable to WWTP operations optimization.
Evaluating Strass WWTP performance, including interviews with the plant operations staff.
Formalizing and extending the approaches used by the Strass team to quantify and evaluate the sustainability of treatment plant operations, and developing an approach to adapt them to the North American reality.

These case studies focus on the CH4 emissions from wastewater treatment in photosynthetic oxidation ponds and facultative sludge lagoons. These area-intensive processes are for cryophilic-to-mesophilic treatment and storage and are uncovered, except for a layer of aerobic liquid. Pond/lagoon treatment technologies represent some of the lowest energy processes available and as such are attractive options from an indirect GHG perspective. While it is intuitive that sludge treatment lagoons have significant anaerobic zones, oxidation ponds have also been shown to develop anaerobic layers, particularly in the deeper portions. Literature also suggests that CH4 evolution is mitigated by methanotrophic bacteria in the water column that can aerobically oxidize CH4, as occurs naturally in lakes and other environments. Because each system has potentially significant anaerobic volumes, quantifying the levels of CH4 emissions would provide insight into the significance of direct CH4 emissions and whether improvements are warranted to address fugitive emissions in these otherwise very sustainable technologies. These tasks provide a better understanding of the wastewater treatment industry's true impacts from a GHG standpoint. With that understanding better solutions may be developed to remediate their impact as warranted by their significance.

In 2008, the New York State Energy Research and Development Authority (NYSERDA) published the "Statewide Assessment of Energy Use by the Municipal Water and Wastewater Sector" documenting 2003/2004 energy use at New York State wastewater facilities. Since the publication of these data, interest in energy efficiency and energy generation has grown considerably. Survey data indicated that a third of the respondents had completed capital projects to reduce energy use, and 65 percent indicated that they have future energy projects planned. At the same time, regulatory and technology changes such as tighter nutrient limits have added to many plants' electrical demands.

This research assesses the magnitude of energy performance shifts over the past 10 years based on the net effect of efficiency gains, increased electrical production, and increased process equipment loads. In facilities larger than 75 mgd, an overall trend toward increased average electrical energy consumption was observed, with recent implementation of nutrient removal being the most significant factor in this trend. Small and medium-sized facilities (less than 75 mgd) appear to be slightly improving their energy performance based on analysis of biochemical oxygen demand (BOD)-normalized energy metrics (kilowatt-hours per pound of BOD). Water resource recovery facilities with more developed energy approaches in their organization were more likely to have completed capital projects, operational optimization, and building-related improvements to reduce energy use.

Available as eBook only.


Methane (CH4) production from sewers is a suspected, yet relatively undocumented source of greenhouse gases (GHGs). The Intergovernmental Panel on Climate Change (IPCC) published the "2006 IPCC Guidelines for National Greenhouse Gas Inventories" which states that "In most developed countries and in high-income urban areas in other countries, sewers are usually closed and underground. Wastewater in closed underground sewers is not believed to be a significant source of CH4." CH4 is a greenhouse gas that has a global warming impact that is 21 times that of carbon dioxide (CO2) and as such is of heightened interest in GHG modeling and inventories.



The goal of the first phase of the investigation was to determine if CH4 could be detected in the wetwells and forebays of a sanitary wastewater collection system. During that initial phase, methane emissions were quantified from DeKalb County's 64 pumping stations. The results of this investigation documented that approximately 1,000 MT of carbon dioxide equivalents (CO2e) are emitted each year from CH4 evolution at pumping stations serving roughly half of DeKalb's residents, 350,000 citizens, while moving approximately 50 mgd of wastewater. While 940 MT CO2e/yr were quantified, significant sources of under reporting are thought to exist, potentially masking CH4 emissions estimated between 2 and 5 times greater than those quantified under Phase 1. One potential such source was thought to be manholes receiving force main discharges.



During Phase 2 of this project, continuous gaseous- and liquid-phase monitoring were conducted at the discharge of a 16-inch, 3.3-mile-long force main from the Honey Creek Pumping station. Liquid phase sampling during this phase showed that 8.87 kg of CH4 were emitted per day at the force main receiving manhole during the summer months. The continuous monitoring data was used to calibrate a process model developed by the University of Queensland to predict CH4 and hydrogen sulfide evolution by simulating a force main as a plug-flow, fixed-film reactor. The model was then used to simulate force main CH4 emissions over a calendar year using historical flow and monthly average temperatures. This effort calculated emissions of 52 MT of CO2e/year.

After manpower, energy is the highest operating cost item for most the wastewater utilities. Over the last decade, the implementation of new technologies to meet new effluent limits and water quality standards has considerably increased energy consumption by the sector. The price of energy has also substantially increased in the same period. In North America and Europe, some utilities have reported significant increases in energy costs in recent years, and with oil prices continuing to fluctuate, further substantial increases in operating costs could be expected. Those increases will be compounded by the need to meet additional new regulations that will require energy-intensive treatment processes to achieve tight standards. High energy consumption will affect the wastewater industry worldwide and is inextricably linked to the issue of Climate Change.


Through its Optimization Challenge program, the Water Environment Research Foundation (WERF) is currently participating in the Global Water Research Coalition's (GWRC) project titled Energy Efficiency in the Water Industry: A Compendium of Best Practices and Case Studies. The objective of the GWRC project is to develop a Compendium of best practice (worldwide) in the energy-efficient design and operation of water industry assets. For this project, WERF is serving the role of North America wastewater practice coordinator. Through this assignment, WERF intends to define specific recommendations regarding: Incremental improvements in energy efficiency through optimization of existing assets and operations More substantial improvements in energy efficiency from the adoption of novel (but proven at full scale) technologies As part of the GWRC project, WERF has developed this report summarizing existing information on well-established energy optimization/energy recovery best practices, as well as documenting a series of case studies of novel (yet full-scale proven) technologies/practices in wastewater treatment in primarily North America.

Resources end up in wastewater through inefficient consumption. As a result, wastewater contains reusable water, carbon (energy) and nutrients (nitrogen, phosphorus and sulfur) that could be recovered or reused. Meanwhile, current treatment objectives are to produce an acceptable quality of water for reuse or discharge at the lowest life cycle cost. Most of the current treatment processes manage carbon and nutrients as wastes to be removed, and do not attempt to capitalize on these resources inherent in wastewater. In the context of sustainability and climate change, the next generation of wastewater treatment processes should focus on resource recovery (water reuse, energy/carbon recovery and nutrient recovery) as much as they currently do on treatment. The future goal is for wastewater treatment of domestic wastewater to have a minimal carbon footprint, and to be 100% self-sustainable with regards to energy, carbon, and nutrients, while achieving a discharge or reuse quality that preserves the quality of the receiving waters.


In May 2009, the Water Environment Research Foundation (WERF) convened a work group of international experts in the wastewater sector to develop a Wastewater Treatment Technology Roadmap which will identify possible routes to sustainable wastewater treatment in a carbon-constrained world. The resultant Technology Roadmap report identifies pathways toward sustainable wastewater systems over the next few decades, including various approaches the sector could utilize over the 20-30 year planning horizon.



The Technology Roadmap describes the current status of wastewater technologies, projects future treatment quality requirements, identifies research needs, and summarizes ongoing activities to meet the perceived future objectives such as reducing the carbon footprint while achieving lower nutrient levels. Work group participants brainstormed possible technology concepts which can be reasonably expected to produce actionable results that can be implemented by interested wastewater utilities. The participants considered typical and atypical approaches to optimizing carbon and nutrient management at WWTPs. Typical approaches include the evaluation of process modeling opportunities and constraints, and incremental resource and carbon management optimization techniques. Atypical approaches will be even more important to the future of wastewater resource reclamation. As an additional outcome, several work group members suggested conceptual and sustainable "plant of the future" treatment systems not constrained by existing infrastructure. Participants discussed their "Plant of the Future" concepts which can be expected to generate opportunities and research needs related to energy sources within treatment plants, changing wastewater characteristics, decentralized treatment, increased nutrient recovery and management, and total water reuse.

Anaerobic digestion of sludge at wastewater treatment plants and biological decay of organic matter in landfills primarily generates methane (CH4) and carbon dioxide (CO2) along with other secondary by-products. Although, CH4 evolved from such processes is routinely captured for beneficial use (combined heat and power generation), the unused CH4 generated from these processes is routinely flared for safe and less environmentally harmful disposal. Due to high inert gas and moisture content, these gases have a low heating value and lower flaring-efficiency at the flares. Furthermore, environmental factors such as wind velocity, atmospheric pressure and relative humidity also play a significant role in affecting the combustion efficiency, especially at the unconfined and unassisted 'candlestick' flares. However, the prevalent understanding is that flaring provides nearly complete combustion of CH4 contained within the digester or landfill gas and converts it to CO2 and flue gases contain insignificant amounts of CH4 or GHG emissions. The most widely accepted reference to estimate flaring-efficiency, EPA's Emissions Factors and AP-42 (1998), recommends using a value between 98 to 100% (99% as a default) as flaring-efficiency for the candlestick flares operating on landfill or digester gas. However, simply assuming 99% combustion efficiency can significantly underestimate the GHG emissions.


Leveraging the past research work done at the University of Alberta's (UoA's) Flare Research Group, an emissions calculation method has been developed as part of this research project. This method has been converted into a stand-alone tool, the Flare Efficiency Estimator (FEE). FEE has flare gas composition and flaring conditions such as flare gas throughput, flare size, wind speed, gas temperature, ambient temperature, and atmospheric pressure input parameters. FEE can help estimate the combustion efficiency as well as fugitive GHG emissions from the digester gas and landfill gas flares. FEE was originally developed under this project (U2R08) and expanded further under the OWSO11C10 project to include the NOx emissions. The most current version of FEE uses the 100-year global warming potential (GWP) of CH4 as 25 CO2e (IPCC, 2007).



To demonstrate the use of the FEE to estimate fugitive GHG emissions, data from two wastewater treatment plants (WWTP), one from Georgia and another from Tennessee are presented as case studies. These case studies were developed using the first version of FEE and did not include NOx emissions estimate. For the Tennessee case study, gas flaring data for a 100-mgd capacity WWTP were analyzed. With an average digester gas flaring volume of nearly 203,000 ft3/day and 70% CH4 fraction, FEE estimated a flaring-efficiency of 95.5%. Which meant an estimated 834 MT CO2e/yr were emitted in the atmosphere due to flaring inefficiency. Using the 99% flaring-efficiency assumption per EPA AP-42, these estimates would have been underreported by approximately 649 MT CO2e/yr. Similarly, for the Georgia case study, gas flaring data and prevalent flaring conditions for an 80-mgd capacity plant were evaluated. With an average digester gas flaring volume of nearly 133,000 ft3/day and 65% CH4 fraction, FEE estimated a flaring-efficiency of 94.5% which meant an estimated 759 MT CO2e/yr were emitted in the atmosphere due to flaring inefficiency. Using the 99% flaring-efficiency assumption per EPA AP-42, these estimates would have been only 138 MT CO2e/yr, an underestimating of GHG emissions by approximately 621 MT CO2e/yr.



FEE is available online from this NYSERDA webpage: http://www.nyserda.ny.gov/en/Commercial-and-Industrial/Sectors/Municipal-Water-and-Wastewater-Facilities/Final-Reports-for-Water-and-Wastewater-Technology-and-Demonstration-Projects.aspx