Energy-efficient Wastewater Treatment by Microbial Fuel Cells: Scaling Up and Optimization

Ge, Zheng

06 November 2015

Microbial fuel cells (MFCs) are potentially advantageous as an energy-efficient approach to wastewater treatment. For single-chamber tubular MFCs, anode effluent is used as catholyte instead of tap water or buffer solutions. Therefore, exposing cathode electrode to atmosphere could be also considered as a passive aeration for further aerobic oxidation of organics and nitrification. Based on several bench-scale studies, a 200-L scale MFC system with passive aeration process has been developed for treating actual municipal wastewater after primary clarification. The integrated system was able to remove over 80% organic contaminants and solid content from primary effluent. Through parallel and serial electricity connection, the power output of ~200 mW and the conversion efficiency of ~80% for charging capacitors were achieved by using commercially available energy harvesting device (BQ 25504). The treatment system is energy-efficient for the energy saving from aeration and sludge treatment while partial energy recovery as direct electricity can be utilized on site to power small electric devices. However, the post treatments are required to polish the effluent for nutrients removal. / Ph. D.

microbial fuel cells

wastewater

energy recovery

Optimization

scaling up

Challege and Opportunities of Membrane Bioelctrochemical Reactors for Wastewater Treatment

Li, Jian

26 April 2016

Microbial fuel cells (MFCs) are potentially advantageous as an energy-efficient approach for wastewater treatment. Integrating membrane filtration with MFCs could be a viable option for advanced wastewater treatment with a low energy input. Such an integration is termed as membrane bioelectrochemical reactors (MBERs). Comparing to the conventional membrane bioreactors or anaerobic membrane bioreactors, MBER could be a competitive technology, due to the its advantages on energy consumption and nutrients removal. By installing the membrane in the cathodic compartment or applying granular activated carbon as fluidized bed materials, membrane fouling issue could be alleviated significantly. In order to drive MBER technology to become a more versatile platform, applying anion exchange membrane (AEM) could be an option for nutrients removal in MBERs. Wastewater can be reclaimed and reused for subsequent fermentation use after a series MFC-MBR treatment process. Such a synergistic configuration not only provide a solution for sustainable wastewater treatment, but also save water and chemical usage from other non-renewable resource. Integrating membrane process with microbial fuel cells through an external configuration provides another solution on sustainable wastewater treatment through a minimal maintenance requirement. / Ph. D.

Microbial fuel cells

Wastewater

Energy recovery

Fouling

Optimization

A Comparison of Two Air Compressors for PEM Fuel Cell Systems

Kulp, Galen W.

15 January 2002

Proton exchange membrane (PEM) fuel cells are considered one of the best potential alternative power sources for automobiles. For this application, high efficiency and high power density are required. Pressurizing the fuel cell system can give higher efficiency, higher power density and better water balance characteristics for the fuel cell, but pressurization uses a percentage of the fuel cell output power. The compressor used to elevate the pressure has a direct effect on the system efficiency and water balance characteristics. A variety of compressors are being developed for fuel cell applications. Two compressor and expander technologies are discussed in this paper: the Opcon 1050 positive displacement twin-screw compressor and expander, and a Honeywell turbocompressor and expander. The effect of these compressors and expanders on the system at maximum load, low load, and set minimum airflow are examined. The effects of ambient conditions, stack temperature, and increased twin-screw compressor pressure are also examined. The turbocompressor proves to be a superior machine in terms of efficiency, and therefore offers the most promising effect on system efficiency of the two compressors. The twin-screw compressor, on the other hand, offers more flexible pressure ratio and better water balance characteristics at low fuel cell loads, which is an important factor with PEM fuel cell systems. Increased ambient and stack temperature has a significant negative effect on the water balance and a small positive effect on efficiency. Increasing the pressure for the twin-screw compressor significantly improves the water balance characteristics with some loss in efficiency. These results show the importance of determining the system operating range and operating conditions in the choice of a compressor for a fuel cell system / Master of Science

Automotive

Compressor Technology

Alternative Energy Sources

Fuel Cells

Multiphase Isolated DC-DC Converters for Low-Voltage High-Power Fuel Cell Applications

Moon, Seung Ryul

22 May 2007

Fuel cells provide a clean and highly efficient energy source for power generation; however, in order to efficiently utilize the energy from fuel cells, a power conditioning system is required. Typical fuel cell systems for stand-alone and utility grid-tied stationary power applications are found mostly with low nominal output voltages around 24 V and 48 V, and power levels are found to be 3 to 10 kW [1][2]. A power conditioning system for such applications generally consists of a dc-dc converter and a dc-ac inverter, and the dc-dc converter for low-voltage, high-power fuel cells must deal with a high voltage step-up conversion ratio and high input currents. Although many dc-dc converters have been proposed, most deal with high input voltage systems that focus on step-down applications, and such dc-dc converters are not suitable for low-voltage, high-power fuel cell applications. Multiphase isolated dc-dc converters offer several advantages that are very desirable in low-voltage, high-power fuel cell applications. First, a multiphase is constructed with paralleled phases, which increase power rating and current handling capability for high input current. Second, an interleaving control scheme produces a high operating frequency with a low switching frequency, and the high operating frequency reduces size of passive components. Thirdly, use of a transformer provides electrical isolation and a high conversion ratio. Lastly, several multiphase converters are capable of soft-switching operation, which increases converter efficiency. This thesis examines two highly efficient, soft-switching dc-dc converters that are targeted for fuel cell applications. The thesis also describes the converters' basic operating principles and analyzes performance for low-voltage, high-power fuel cell applications. 5-kW prototypes for each converter are built and tested with a fuel cell simulator. Experimental switching waveforms and efficiency profiles are shown to support the described basic principles and the analysis. Major features and differences between these two converters are also discussed. / Master of Science

dc-dc converters

fuel cells

soft switching

multiphase

Novel Aspects of the Conduction Mechanisms of Electrolytes Containing Tetrahedral Moieties

Kendrick, E., Kendrick, John, Orera, A., Panchmatia, P., Islam, M.S., Slater, P.R.

09 1900

No / Traditionally materials with the fluorite and perovskite structures have dominated the research in the area of oxide ion/proton conducting solid electrolytes. In such cases, the key defects are oxide ion vacancies, and conduction proceeds via a simple vacancy hopping mechanism. In recent years, there has been growing interest in alternative structure types, many of which contain tetrahedral moieties. For these new systems, an understanding of the accommodation of defects and the nature of the conduction mechanism is important for the optimisation of their conductivities, as well as to help target related structures that may display high oxide ion/proton conduction. Computer modelling studies on a range of systems containing tetrahedral moieties are presented, including apatite-type La9.33+xGe6O26+3x/2, cuspidine-type La4Ga2-xTixO9+x/2 and La1-xBa1+xGaO4-x/2. The type of anion defect (vacancy or interstitial), their location and the factors affecting their incorporation are discussed. In addition, modelling data to help to understand their conduction mechanisms are presented, showing novel aspects including the important role of the tetrahedral moieties in the conduction processes.

Fuel Cells

Modelling

Ionic Conductivity

Properties

Solid Oxide Fuel Cell

Novel Aspects of the Conduction Mechanisms of Electrolytes Containing Tetrahedral Moieties

Kendrick, E., Kendrick, John, Orera, A., Panchmatia, P., Islam, M.S., Slater, P.R.

04 1900

No / Traditionally materials with the fluorite and perovskite structures have dominated the research in the area of oxide ion/proton conducting solid electrolytes. In such cases, the key defects are oxide ion vacancies, and conduction proceeds via a simple vacancy hopping mechanism. In recent years, there has been growing interest in alternative structure types, many of which contain tetrahedral moieties. For these new systems, an understanding of the accommodation of defects and the nature of the conduction mechanism is important for the optimisation of their conductivities, as well as to help target related structures that may display high oxide ion/proton conduction. Computer modelling studies on a range of systems containing tetrahedral moieties are presented, including apatite-type La9.33+xGe6O26+3x/2, cuspidine-type La4Ga2¿xTixO9+x/2 and La1¿xBa1+xGaO4¿x/2. The type of anion defect (vacancy or interstitial), their location and the factors affecting their incorporation are discussed. In addition, modelling data to help to understand their conduction mechanisms are presented, showing novel aspects including the important role of the tetrahedral moieties in the conduction processes

Fuel Cells

Ionic Conductivity

Modelling

Solid Oxide Fuel Cell

High frequency link inverters for fuel cell based systems

Kaluvala, Shilpa

01 October 2003

No description available.

Electric inverters; Fuel cells

Electrical and Computer Engineering

Engineering

The design and manufacturing of scandia-ceria stabilized zirconia ceramics for use as electrolyte material in solid oxide fuel cells

Bean, Glenn E.

01 January 2009

In order to increase the efficiency and economic viability of solid oxide fuel cells (SOFCs), new materials for the cathode, anode, and electrolyte of the cells must be found. SOFCs have a ceramic electrolyte, which is commonly made of fully stabilized zirconia. Due to increased material degradation rates at elevated temperatures ( ~ 1000°C) of current SOFCs, materials for the manufacture of intermediate temperature SOFCs, which operate in the range of 700-800°C, are currently under study. In this study, the manufacturing process for scandia-ceria stabilized zirconia powder (1 0mol¾ Sc2O3, lmol¾ CeO2, 89mol% ZrO2), from Daiichi Kigenso Kagaku Kogyo (DKKK) is developed, including tape casting and sintering procedures to result in pellets of high enough quality to produce single button cells. It is found that a slip prepared with about 44 wt% zirconia powder and increased proportions of solvents, dispersant, binder and plasticizers produces a favorable viscosity of about 7 40cP after deairing, and will produce tapes that are reasonably smooth and of stable thickness. Since the single cell will be structurally based upon this electrolyte material, the physical properties of the pellets are important, in addition to the electrochemical properties of the constituent materials. Tapes cast at 500µm, at 50% feed rate with a 50°C drying temperature, laminated and sintered at 1500°C on setter plates will produce flat, smooth, stiff pellets for the production of single buttons for use as the electrolyte. Cathode (50-50 mixture of La0.6Sr0_4Fe0_8Co0.2O3 + 20mol% Gd2O3 80mol% CeO2) and Anode (35 wt% DKKK powder, 65 wt% NiO) materials were hand-painted on to either side of the electrolyte and sintered to create a complete SOFC cell consisting of cathode, electrolyte, and anode.

ceria; Tape casting; Zirconia

Engineering

Development of alternative cathodes for intermediate temperature solid oxide fuel cells

Kim, Junghyun

05 November 2009

text

Cathodes

Solid oxide fuel cells

Perovskite cathodes

Non-perovskite oxides

Composite cathodes

Thermal expansion

Cobalt-based perovskite cathodes

Fuel cells

The impact of new technologies on shipboard command and control

Oats, Trey D., Erickson, Matthew C.

06 1900

Approved for public release, distribution is unlimited / An investigation of how fuel cells, an integrated power system, and directed energy weapons will affect the shipboard command and control process. The focus is on the implementation of the new technologies onboard near-term and far-term destroyer variants and the resulting changes to the command and control process. / Ensign, United States Naval Reserve

Fuel cells

Directed-energy weapons

Command and control systems

Fuel cells

Integrated power system

Directed energy weapons

Command and control