Terry A Cruse, 551003 Southport Ave, Lisle, IL 60532

6843960, Jan 18, 2005

Jun 12, 2002

10/167832

Michael Krumpelt - Naperville IL, US
Terry Alan Cruse - Lisle IL, US
John David Carter - Bolingbrook IL, US
Jules L. Routbort - Hinsdale IL, US
Romesh Kumar - Naperville IL, US

The University of Chicago - Chicago IL

B22F 300

419 6, 419 9, 419 10, 419 40

A method for preparing compositionally graded metallic plates and compositionally graded metallic plates suitable for use as interconnects for solid oxide fuel cells are provided. The method of the invention, utilizing powder metallurgy, enables making metallic plates of generally any desired composition to meet the corrosion requirements of fuel cells and other applications, and enables making metallic plates of graded composition from one surface of the plate to the other. A powder of the desired alloy composition is obtained, then solvents, dispersants, a plasticizer and an organic binder are added to form a slip. The slip is then formed into a layer on a desired substrate that can be flat or textured. Once dried, the layer is removed from the substrate and the binder is burned out. The layer is sintered in a reducing atmosphere at a set temperature for a predefined duration specific to the materials used and the desired final properties.

7452837, Nov 18, 2008

Jan 22, 2001

10/275537

Kenneth C. Goretta - Downers Grove IL, US
Dileep Singh - Naperville IL, US
Bryant J. Polzin - Mundelein IL, US
Terry Cruse - Lisle IL, US
John J. Picciolo - Lockport IL, US

UChicago Argonne, LLC. - Chacago IL

C04B 35/00

501 951, 2641711, 264640

A method for producing composite ceramic material is provided wherein a core ceramic structure is produced and simultaneously enveloped with a sleeve of similar material.

7632593, Dec 15, 2009

Apr 18, 2006

11/406097

John David Carter - Bolingbrook IL, US
Joong-Myeon Bae - Daejon, KR
Terry Alan Cruse - Lisle IL, US
James Michael Ralph - Fairlawn OH, US
Deborah J. Myers - Lisle IL, US

UChicago Argonne, LLC - Chicago IL

H01M 2/08

429 35, 429 38

A bipolar plate supported solid oxide fuel cell with a sealed anode compartment is provided. The solid oxide fuel cell includes a cathode, an electrolyte, and an anode, which are supported on a metallic bipolar plate assembly including gas flow fields and the gas impermeable bipolar plate. The electrolyte and anode are sealed into an anode compartment with a metal perimeter seal. An improved method of sealing is provided by extending the metal seal around the entire perimeter of the cell between an electrolyte and the bipolar plate to form the anode compartment. During a single-step high temperature sintering process the metal seal bonds to the edges of the electrolyte and anode layers, the metal foam flow field and the bipolar plate to form a gastight containment.

7699916, Apr 20, 2010

May 28, 2008

12/128022

J. David Carter - Bolingbrook IL, US
Jennifer R. Mawdsley - Woodridge IL, US
Suhas Niyogi - Woodridge IL, US
Xiaoping Wang - Naperville IL, US
Terry Cruse - Lisle IL, US
Lilia Santos - Lombard IL, US

The United States of America as represented by the United States Department of Energy - Washington DC

C09D 5/00
C09D 5/08
C09D 201/00
C09D 201/02
C09D 201/04
C09D 201/06
H01M 2/32

106 1405, 106 1444, 106285, 10628719, 10628726, 429 34

A corrosion resistant, electrically-conductive, durable plate at least partially coated with an anchor coating and a corrosion resistant coating. The corrosion resistant coating made of at least a polymer and a plurality of corrosion resistant particles each having a surface area between about 1-20 m/g and a diameter less than about 10 microns. Preferably, the plate is used as a bipolar plate in a proton exchange membrane (PEMFC) fuel cell stack.

2003023, Dec 18, 2003

Jun 12, 2002

10/167917

John Carter - Bolingbrook IL, US
Terry Cruse - Lisle IL, US
James Ralph - Chicago IL, US
Romesh Kumar - Naperville IL, US
Michael Krumpelt - Naperville IL, US

H01M008/12
H01M008/24

429/032000, 429/038000, 264/618000

A solid oxide fuel cell (SOFC) repeat unit includes an oxide electrolyte, an anode, a metallic fuel flow field, a metallic interconnect, and a metallic air flow field. The multilayer laminate is made by casting tapes of the different functional layers, laminating the tapes together and sintering the laminate in a reducing atmosphere. Solid oxide fuel cell stacks are made by applying a cathode layer, bonding the unit into a gas manifold plate, and then stacking the cells together. This process leads to superior mechanical properties in the SOFC due to the toughness of the supporting metallic layers. It also reduces contact resistances in stacking the cells since there is only one physical contact plane for each repeat unit.

2009001, Jan 15, 2009

Jul 9, 2007

11/825815

Brian J. Ingram - Chicago IL, US
Michael Krumpelt - Naperville IL, US
Terry A. Cruse - Lisle IL, US

H01M 4/86
H01B 1/02

429 13, 25251912

A composition of matter and method of use of an electrode for intermediate temperature electrochemical devices. An electrode consists essentially of a perovskite based oxide having a composition of LaSrMnCrO and the electrode can be used at intermediate operating temperatures of 650-800 C.

2010006, Mar 18, 2010

Nov 11, 2009

12/616186

John David Carter - Bolingbrook IL, US
Joong-Myeon Bae - Daeion, KR
Terry Alan Cruse - Lisle IL, US
James Michael Ralph - Fairlawn OH, US
Deborah J. Myers - Lisle IL, US

UCHICAGO ARGONNE, LLC - Chicago IL

H01M 8/10

296232

Methods of sealing a bipolar plate supported solid oxide fuel cell with a sealed anode compartment are provided. The solid oxide fuel cell includes a cathode, an electrolyte, and an anode, which are supported on a metallic bipolar plate assembly including gas flow fields and the gas impermeable bipolar plate. The electrolyte and anode are sealed into an anode compartment with a metal perimeter seal. An improved method of sealing is provided by extending the metal seal around the entire perimeter of the cell between an electrolyte and the bipolar plate to form the anode compartment. During a single-step high temperature sintering process the metal seal bonds to the edges of the electrolyte and anode layers, the metal foam flow field and the bipolar plate to form a gastight containment.

2010006, Mar 18, 2010

Apr 23, 2009

12/429048

Terry A. Cruse - Lisle IL, US
Michael Krumpelt - Naperville IL, US
Brian J. Ingram - Chicago IL, US

UCHICAGO ARGONNE, LLC - Chicago IL

F16J 15/02

277654

Compressive composite seals for solid oxide fuel cell applications are provided. A compressive composite seal structure includes a glass phase to provide a gas tight seal, a reinforcing secondary phase to provide mechanical stability, and a compressive core. The compressive core is filled with an inert gas or air, providing a degree of compressibility, or alternatively is filled with a selected material to provide a more specific degree of compressibility and strength, such as a lower melting point glass. The compressive composite seal structure maintains an effective seal during the operating conditions of the SOFC. The self healing glass phase with the reinforcing secondary phase providing mechanical stability provides an elastic response at high temperature, effectively reduces crack propagation and if the temperature or pressure goes too high, the seal remains reliable and effective.