METHODS AND APPARATUS FOR STIMULATING AND MANAGING POWER FROM MICROBIAL FUEL CELLS
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Abstract
Inventive aspects of the present disclosure generally relates to fuel cells and, in particular, to fuel cells that can use microorganisms (microbes) to oxidize fuel. Certain aspects are directed to fuel cells that operate at relatively elevated temperatures. Such temperatures, for example, can increase the metabolisms of the microorganisms within the fuel cell. The elevated temperatures may be achieved, for instance, by using a thermal insulator, such as a vacuum jacket. Microorganism metabolism may also be improved, in some aspects of the invention, by exposing the microorganisms to growth promoters such as fertilizer, nitrogen sources, biomass, etc. The microorganisms, in some embodiments of the invention, may be anaerobic or microaerophilic and can be obtained, for example, from the soil, compost, peat, sewage, bogs, wastewater, or other organic-rich matrices. Another inventive aspect relates to novel electrodes for use in fuel cells, such as microbial fuel cells. The electrode, in some cases, may be flexible and/or porous. In certain embodiments, the electrode may be treated, e.g., with acid and/or biomass, to improve performance. Such treatments may facilitate microorganism metabolism. Yet another inventive aspect relates to a proton exchange interface between an anode and a cathode in a fuel cell, such as a microbial fuel cell. The proton exchange interface may be designed to allow protons and/or gases to pass through, but, in some cases, minimizes or eliminates mixing between the anode and the cathode. Still another inventive aspect generally relates to an energy management system for use with such fuel cells, including microbial fuel cells. Yet another aspect relates to switching systems that allow a plurality of fuel cells (which may be housed in one vessel or separate vessels) to sustain net power output that is greater than the sum of the individual microbial fuel cells under constant load. In some cases, the energy management system can store and manage energy from the fuel cell such that conventional operating voltages may be provided to a variety of loads having various instantaneous and average power requirements. Other inventive aspects relate to techniques for forming such fuel cells and fuel cell components, techniques for using such fuel cells, systems involving such fuel cells, and the like:
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Citations
189 Claims
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1-169. -169. (canceled)
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170. An energy management apparatus for at least one microbial fuel cell, the apparatus comprising:
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at least one first energy storage component or load to store first energy provided by the at least one microbial fuel cell; and a comparator circuit, coupled to the at least one first energy storage component or load, to compare a first voltage across the at least one first energy storage component or load to a first set point, the comparator circuit configured to implement a hysteresis window defined by a first predetermined level above the first set point and a second predetermined level below the first set point, such that an output of the comparator circuit changes from a first logic state to a second logic state when the first voltage is at or above the first predetermined level, and the output of the comparator circuit changes from the second logic state to the first logic state when the first voltage is at or below the second predetermined level. - View Dependent Claims (171, 172, 173, 174, 175, 176, 177, 178, 179, 180, 181, 182)
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183. An energy management method for at least one microbial fuel cell, comprising:
A) intermittently coupling the at least one microbial fuel cell to a load that draws current from the at least one microbial fuel cell. - View Dependent Claims (184, 185, 186, 187)
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188. An energy management apparatus for at least one microbial fuel cell, the apparatus comprising:
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at least one input energy storage device to receive first energy from a cathode and an anode of the at least one microbial fuel cell; and a switching circuit to intermittently couple the anode and/or the cathode of the at least one microbial fuel cell to a load based at least in part on a voltage potential between the anode and the cathode of the at least one microbial fuel cell. - View Dependent Claims (189)
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Specification
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Current AssigneePresident and Fellows of Harvard College (Harvard Corporation)
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Original AssigneePresident and Fellows of Harvard College (Harvard Corporation)
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InventorsKauffman, Peter Carr, Girguis, Peter Riad
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Application NumberUS12/311,165Publication NumberTime in Patent OfficeDaysField of SearchUS Class Current429/2CPC Class CodesH01M 16/006 of fuel cells with recharge...H01M 2300/0071 OxidesH01M 4/8605 Porous electrodesH01M 4/8839 PaintingH01M 4/8878 Treatment steps after depos...H01M 4/96 Carbon-based electrodesH01M 8/0234 Carbonaceous materialH01M 8/0245 in the form of layered or c...H01M 8/04007 related to heat exchangeH01M 8/04201 Reactant storage and supply...H01M 8/04544 VoltageH01M 8/04559 of fuel cell stacksH01M 8/04567 of auxiliary devices, e.g. ...H01M 8/0488 of fuel cell stacksH01M 8/1016 characterised by the electr...H01M 8/16 Biochemical fuel cells, i.e...Y02E 60/10 Energy storage using batteriesY02E 60/50 Fuel cells
