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公开(公告)号:US11978931B2
公开(公告)日:2024-05-07
申请号:US17173786
申请日:2021-02-11
Inventor: Christopher Howard , Brandon J. O'Neill , Paul J. Rubas , Frank Hershkowitz , Lu Han , Lawrence J. Novacco , Frank J. Dobek, Jr. , Keith E. Davis , Brian Bullecks
IPC: H01M8/04082 , H01M8/04089 , H01M8/244 , H01M8/2485
CPC classification number: H01M8/04201 , H01M8/04089 , H01M8/244 , H01M8/2485
Abstract: Molten carbonate fuel cell configurations are provided that allow for introduction of an anode input gas flow on a side of the fuel cell that is adjacent to the entry side for the cathode input gas flow while allowing the anode and cathode to operate under co-current flow and/or counter-current flow conditions. It has been discovered that improved flow properties can be achieved within the anode or cathode during co-current flow or counter-current flow operation by diverting the input flow for the anode or cathode into an extended edge seal region (in an extended edge seal chamber) adjacent to the active area of the anode or cathode, and then using a baffle to provide sufficient pressure drop for even flow distribution of the anode input flow across the anode or cathode input flow across the cathode. A second baffle can be used to create a pressure drop as the anode output flow or cathode output flow exits from the active area into a second extended edge seal region (in a second extended edge seal chamber) prior to leaving the fuel cell.
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Patent Agency Ranking
公开(公告)号:US20240140792A1
公开(公告)日:2024-05-02
申请号:US18499472
申请日:2023-11-01
Inventor: Everett J. O'NEAL , David C. Dankworth , Lu Han , Sarah E. Feicht , Anastasios I. Skoulidas
CPC classification number: C01B3/26 , B01J19/0066 , B01J19/2485 , C01B2203/0238 , C01B2203/06 , C01B2203/1235
Abstract: Systems and methods are provided for performing both reforming and partial oxidation as part of the reaction step of a reaction cycle in a cyclic reaction environment such as a reverse flow reaction environment, where heat is provided by direct heating during a regeneration step. In some aspects, performing a combination of reforming and partial oxidation can allow for higher conversion of hydrocarbons than reforming alone while reducing or minimizing the peak temperatures within the cyclic reaction environment. In some aspects, performing both reforming and partial oxidation can also allow for an improved molar ratio of H2 to CO in the resulting effluent from the conversion reaction (relative to partial oxidation) while still maintaining high total conversion.
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公开(公告)号:US12095129B2
公开(公告)日:2024-09-17
申请号:US18110097
申请日:2023-02-15
Inventor: Everett J. O'Neal , Lu Han , Carla S. Pereira , Rodrigo F. Blanco Gutierrez , Timothy M. Healy , Carl A. Willman , Hossein Ghezel-Ayagh , Frank J. Dobek, Jr.
IPC: H01M8/14 , H01M4/86 , H01M8/04119 , H01M8/0438 , H01M8/0444 , H01M8/04746 , H01M8/04791 , H01M8/0612 , H01M8/0637
CPC classification number: H01M8/145 , H01M8/0618 , H01M4/861 , H01M4/8636 , H01M8/04179 , H01M8/04388 , H01M8/04395 , H01M8/04402 , H01M8/0441 , H01M8/04462 , H01M8/0447 , H01M8/04477 , H01M8/04753 , H01M8/04798 , H01M8/0625 , H01M8/0631 , H01M8/0637 , H01M8/14 , H01M2008/147 , H01M2300/0051
Abstract: A reforming element for a molten carbonate fuel cell stack and corresponding methods are provided that can reduce or minimize temperature differences within the fuel cell stack when operating the fuel cell stack with enhanced CO2 utilization. The reforming element can include at least one surface with a reforming catalyst deposited on the surface. A difference between the minimum and maximum reforming catalyst density and/or activity on a first portion of the at least one surface can be 20% to 75%, with the highest catalyst densities and/or activities being in proximity to the side of the fuel cell stack corresponding to at least one of the anode inlet and the cathode inlet.
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公开(公告)号:US20240047725A1
公开(公告)日:2024-02-08
申请号:US18136699
申请日:2023-04-19
Inventor: Keith E. Davis , Frank Hershkowitz , Lu Han , Clay R. Sutton , Paul J. Rubas
IPC: H01M8/2475 , H01M8/2483 , H01M8/2484 , H01M8/04014 , H01M8/04089 , H01M8/04701 , H01M8/249
CPC classification number: H01M8/2475 , H01M8/2483 , H01M8/2484 , H01M8/04014 , H01M8/04089 , H01M8/04708 , H01M8/249 , H01M2250/10
Abstract: A module assembly is provided including a fuel cell stack assembly, a heat exchanger, and a housing enclosing the fuel cell stack assembly and the heat exchanger. The heat exchanger is configured to receive process gas from an external source and output said process gas to the fuel cell stack assembly, and configured to receive process gas from the fuel cell stack assembly and output said process gas. A fuel cell power plant is provided including a module assembly with a first end, a racking structure configured to hold the module assembly, balance of plant equipment, and ducting configured to provide fluid communication between the balance of plant equipment and the first end of the module assembly. The module assembly and the racking structure are configured such that the module assembly may be removed from the racking structure in a direction away from the first end of the module assembly.
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公开(公告)号:US11742508B2
公开(公告)日:2023-08-29
申请号:US16696821
申请日:2019-11-26
Inventor: Everett J. O'Neal , Lu Han , Carla S. Pereira , Rodrigo F. Blanco Gutierrez , Timothy M. Healy , Carl A. Willman , Hossein Ghezel-Ayagh , Frank J. Dobek, Jr.
IPC: H01M8/14 , H01M8/0612 , H01M8/04791 , H01M8/0637 , H01M8/0444 , H01M8/04119 , H01M4/86 , H01M8/0438 , H01M8/04746
CPC classification number: H01M8/145 , H01M8/0618 , H01M4/861 , H01M4/8636 , H01M8/0441 , H01M8/0447 , H01M8/04179 , H01M8/04388 , H01M8/04395 , H01M8/04402 , H01M8/04462 , H01M8/04477 , H01M8/04753 , H01M8/04798 , H01M8/0625 , H01M8/0631 , H01M8/0637 , H01M8/14 , H01M2008/147 , H01M2300/0051
Abstract: A reforming element for a molten carbonate fuel cell stack and corresponding methods are provided that can reduce or minimize temperature differences within the fuel cell stack when operating the fuel cell stack with enhanced CO2 utilization. The reforming element can include at least one surface with a reforming catalyst deposited on the surface. A difference between the minimum and maximum reforming catalyst density and/or activity on a first portion of the at least one surface can be 20% to 75%, with the highest catalyst densities and/or activities being in proximity to the side of the fuel cell stack corresponding to at least one of the anode inlet and the cathode inlet.
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公开(公告)号:US20230197994A1
公开(公告)日:2023-06-22
申请号:US18110097
申请日:2023-02-15
Inventor: Everett J. O'Neal , Lu Han , Carla S. Pereira , Rodrigo F. Blanco Gutierrez , Timothy M. Healy , Carl A. Willman , Hossein Ghezel-Ayagh , Frank J. Dobek, JR.
IPC: H01M8/14 , H01M8/0612
CPC classification number: H01M8/145 , H01M8/0618 , H01M2008/147 , H01M8/04798
Abstract: A reforming element for a molten carbonate fuel cell stack and corresponding methods are provided that can reduce or minimize temperature differences within the fuel cell stack when operating the fuel cell stack with enhanced CO2 utilization. The reforming element can include at least one surface with a reforming catalyst deposited on the surface. A difference between the minimum and maximum reforming catalyst density and/or activity on a first portion of the at least one surface can be 20% to 75%, with the highest catalyst densities and/or activities being in proximity to the side of the fuel cell stack corresponding to at least one of the anode inlet and the cathode inlet.
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