Patent application number | Description | Published |
20110003217 | WICKING LAYER FOR MANAGING MOISTURE DISTRIBUTION IN A FUEL CELL - An exemplary device for managing moisture content within a fuel cell includes a reactant distribution plate having a plurality of members that establish reactant flow channels that are open on at least one side of the plate. A wicking layer is against the one side of the plate. The wicking layer includes a first portion that is uninterrupted and covers over at least some of the channels. A second portion of the wicking layer extends along ends of at least some of the members such that sections of the channels coextensive with the second portion are open toward the one side. | 01-06-2011 |
20110020732 | FUEL CELL COMPONENT WITH INTERDIGITATED FLOW FIELDS - An exemplary flow field plate for use in a fuel cell includes a plurality of inlet flow channels. A plurality of outlet flow channels are also included. The flow channels are arranged such that at least two of the inlet flow channels are immediately adjacent each other on a first side of the two of the inlet flow channels. At least one of the outlet flow channels is immediately adjacent each of the two inlet flow channels on a second, opposite side of each of the two inlet flow channels. | 01-27-2011 |
20110033758 | POROUS FLOW FIELD PLATE FOR MOISTURE DISTRIBUTION CONTROL IN A FUEL CELL - A flow field plate for use in a fuel cell includes a porous, wettable plate body. A plurality of flow channels are arranged on the body such that an inlet portion of a first flow channel is adjacent an outlet portion of a second flow channel. Moisture from a fluid in the outlet portion of the second flow channel can move through the body of the porous, wettable plate from the outlet portion of the second flow channel toward the adjacent inlet portion of the first flow channel. | 02-10-2011 |
20110207004 | POROUS FLOW FIELD PLATE FOR MOISTURE DISTRIBUTION CONTROL IN A FUEL CELL - A flow field plate for use in a fuel cell includes a porous, wettable plate body including a first reactant gas channel having an inlet portion, a second reactant gas channel having an outlet portion that is adjacent the inlet portion of the first reactant gas channel, and at least one moisture reservoir fluidly connected with pores of the porous, wettable plate body. The at least one moisture reservoir can selectively collect and release moisture received from a reactant gas in the outlet portion to thereby selectively move the moisture from the outlet portion toward the adjacent inlet portion. | 08-25-2011 |
20120009502 | FUEL CELL AND FLOW FIELD PLATE WITH FLOW GUIDE - A flow field plate for use in a fuel cell includes a non-porous plate body having a flow field. The flow field includes a plurality of channels and a flow distribution portion adjacent an end of the plurality of channels for distributing fluid between a manifold and the channels. A flow guide within the flow distribution portion establishes a desired flow distribution between the manifold and the plurality of channels. | 01-12-2012 |
20120015274 | FUEL CELL AND FLOW FIELD PLATE WITH FLOW GUIDES - A flow field plate for use in a fuel cell includes a non-porous plate body having a flow field with a plurality of channels extending between a channel inlet end and a channel outlet end, a first flow distribution portion adjacent the channel inlet end for distributing a fluid to the plurality of channels, and a second flow distribution portion adjacent the channel outlet end for collecting the fluid from the plurality of channels. A first flow guide within the first flow distribution portion establishes a desired flow distribution to the plurality of channels, and a second flow guide within the second flow distribution portion establishes a desired flow distribution from the plurality of channels. | 01-19-2012 |
20120164559 | FUEL CELL AND FLOW FIELD PLATE FOR FLUID DISTRIBUTION - A flow field plate for use in a fuel cell includes a non-porous plate body having a flow field that extends between first and second ends of the non-porous plate body. The flow field includes a plurality of channels having channel inlets and channel outlets, a fluid inlet portion that diverges from the first end to the channel inlets, and a fluid outlet portion that converges from the channel outlets to the second end. A fuel cell including the flow field plate includes an electrode assembly having an electrolyte between an anode catalyst and a cathode catalyst. The flow field of the flow field plate is side by side with the electrode assembly. A method of processing a flow field plate includes forming the flow field in a non-porous plate body. | 06-28-2012 |
20130011770 | MODIFICATION TO STAMPABLE FLOWFIELDS TO IMPROVE FLOW DISTRIBUTION IN THE CHANNELS OF PEM FUEL CELLS - A fuel cell ( | 01-10-2013 |
20130034798 | FUEL CELL WATER MANAGEMENT ARRANGEMENT - An example fuel cell device includes an electrode assembly having two gas diffusion layers (GDLs). One GDL is adjacent to the anode electrode and the other GDL is adjacent to the cathode electrode. Seals on the periphery of the GDLs are configured to block reactant gases from direct mixing within the GDLs. Sealing the perimeter of the GDLs blocks liquid-water flow from exiting the gas diffusion layer. The disclosed example provides an opening in the seal near a fluid exit area of the fuel cell that provides a path for communicating water from the active area through a perimeter portion of the GDL. An example method of managing fluid in a fuel cell includes providing an opening in a perimeter seal of a GDL of the fuel cell. The method communicates a fluid through a channel in the plate and moves water through the opening using the fluid. | 02-07-2013 |
20130101923 | SOLID FLOW FIELD PLATE WITH END TURNS - A method of assembly of a fuel cell plate includes forming channels in a body to provide a flow field. A porous media is inserted into the flow field. The fuel cell plate is a non-porous body including a side having the flow field providing a fluid flow path. The porous media is provided in the fluid flow path. | 04-25-2013 |
20130149619 | HYDRATING A FUEL CELL - An example method of controlling fluid distribution within a fuel cell includes adjusting a flow of a reactant moving within a fuel cell to increase water within a portion of the fuel cell. Another example method of controlling fluid distribution within a fuel cell includes adjusting a flow of fuel entering a fuel cell, a velocity of air entering the fuel cell, or both, so that a first amount of water exiting the fuel cell in a fuel stream is about the same as a second amount of water exiting the fuel cell in an airstream. | 06-13-2013 |
20130157169 | MIXED-IONOMER ELECTRODE - A membrane electrode assembly includes a membrane, an anode catalyst layer and a cathode catalyst layer. The anode catalyst layer is on a first side of the membrane and the cathode catalyst layer is on a second side of the membrane, wherein the second side of the membrane is opposite the first side of the membrane along a first axis. The cathode catalyst layer includes agglomerates formed of a catalyst support supporting catalyst particles, an agglomerate ionomer and an inter-agglomerate ionomer. The agglomerate ionomer surrounds the agglomerates and the inter-agglomerate ionomer is in regions between the agglomerates surrounded by the agglomerate ionomer. The agglomerate ionomer is different than the inter-agglomerate. Methods to produce the catalyst layer are also provided. | 06-20-2013 |
20130196245 | HOT PRESSED, DIRECT DEPOSITED CATALYST LAYER - A method of fabricating a membrane electrode assembly includes the steps of depositing a catalyst ink directly onto a membrane to form a catalyst coated membrane and hot pressing the catalyst coated membrane. The catalyst coated membrane has a catalyst layer that includes a catalyst and an ionomer. | 08-01-2013 |
20130330657 | UNITIZED ELECTRODE ASSEMBLY WITH HIGH EQUIVALENT WEIGHT IONOMER - A catalyst layer for use in a fuel cell includes catalytic nanoparticles and a perfluorosulfonic acid (PFSA) ionomer. The catalytic nanoparticles have a palladium or palladium alloy core and an atomically thin layer of platinum on an outer surface of the palladium or palladium alloy core. The PFSA ionomer has an equivalent weight equal to or greater than about 830. A unitized electrode assembly is also described. | 12-12-2013 |
20140087277 | WICKING LAYER FOR MANAGING MOISTURE DISTRIBUTION IN A FUEL CELL - An exemplary device for managing moisture content within a fuel cell includes a reactant distribution plate having a plurality of members that establish reactant flow channels that are open on at least one side of the plate. A wicking layer is against the one side of the plate. The wicking layer includes a first portion that is uninterrupted and covers over at least some of the channels. A second portion of the wicking layer extends along ends of at least some of the members such that sections of the channels coextensive with the second portion are open toward the one side. | 03-27-2014 |
20140147770 | LOW PLATINUM LOAD ELECTRODE - An electrode for an electrochemical cell includes platinum catalysts, carbon support particles and an ionomer. The carbon support particles support the platinum catalysts, and the ionomer connects the platinum catalysts. The electrode has a platinum less than about 0.2 mg/cm | 05-29-2014 |
20140302423 | FLOW BATTERY WITH CARBON PAPER - A flow battery includes a liquid electrolyte having an electrochemically active specie. A flow field plate includes a first flow field channel and a second flow field channel that is separated from the first flow field channel by a rib. There is a flow path for the liquid electrolyte to flow over the rib between the channels. An electrode is arranged adjacent the flow field plate such that the liquid electrolyte that flows over the rib must flow through the electrode. The electrode includes a carbon paper that is catalytically active with regard to liquid electrolyte. The carbon paper defines a compressive strain of less than 20% at a compressive stress of 0.8 MPa and an uncompressed porosity in the range 60-85%. | 10-09-2014 |