Edward J Domit, 6430 N Hill Rd, Westford, MA 01886

2021005, Feb 18, 2021

Nov 2, 2020

17/086952

- Billerica MA, US
Edward Domit - Westford MA, US
Kevin Beverage - Leominster MA, US
Scott Blanchet - Chelmsford MA, US
John Stang - Columbus IN, US

NUVERA FUEL CELLS, INC. - Billerica MA

H01M 8/0273
C25B 9/06
H01M 8/241
C25B 9/00
C25B 9/20
H01M 8/0247
H01M 8/1004

An electrochemical cell includes a pair of bipolar plates and a membrane electrode assembly between the bipolar plates. The membrane electrode assembly comprises an anode compartment, a cathode compartment, and a proton exchange membrane disposed therebetween. The cell further includes a sealing surface formed in one of the pair of bipolar plates and a gasket located between the sealing surface and the proton exchange membrane. The gasket is configured to plastically deform to create a seal about one of the cathode compartment or the anode compartment. The sealing surface can include one or more protrusions.

2019022, Jul 18, 2019

Jan 17, 2019

16/249931

- Billerica MA, US
Patrick Burand - Winthrop MA, US
Edward Domit - Westford MA, US
Andrew Baugher - Brighton MA, US

Nuvera Fuel Cells, LLC - Billerica MA

H01M 8/0258
H01M 8/0232
H01M 8/1004

The electrochemical cell stack has electrochemical cells stacked along a longitudinal axis. The electrochemical cells have a membrane electrode assembly (MEA) with a cathode catalyst layer, an anode catalyst layer, and a polymer membrane therebetween. The electrochemical cells have an anode plate and a cathode plate with the MEA interposed therebetween, and a cathode flow field between the cathode plate and catalyst layer. The anode plate or the cathode plates are formed of uncoated 316 stainless steel. Portions of the cathode or anode plate have an arithmetic average roughness from about 5 μin to about 35 μin. The cathode flow field is a porous structure. Surface regions on a side of the porous structure facing the MEA are smooth and align with a subgasket of the MEA.

2019022, Jul 18, 2019

Jan 17, 2019

16/249934

- Billerica MA, US
Scott Blanchet - Chelmsford MA, US
Olga Polevaya - Needham MA, US
Edward Domit - Westford MA, US
Andrew Baugher - Brighton MA, US

Nuvera Fuel Cells, LLC - Billerica MA

H01M 8/0258
H01M 8/2483
H01M 8/1004
H01M 8/0232

An electrochemical cell stack having a plurality of electrochemical cells stacked along a longitudinal axis. The electrochemical cells include a membrane electrode assembly comprising a cathode catalyst layer, an anode catalyst layer, and a polymer membrane interposed between the cathode catalyst layer and the anode catalyst layer. The electrochemical cells also include an anode plate and a cathode plate with the membrane electrode assembly interposed therebetween, and the anode plate defines a plurality of channels that form an anode flow field facing the anode catalyst layer. The electrochemical cells further include a cathode flow field positioned between the cathode plate and the cathode catalyst layer, wherein the cathode flow field comprises a porous structure.

2019022, Jul 18, 2019

Jan 17, 2019

16/249946

- Billerica MA, US
Scott Blanchet - Chelmsford MA, US
Olga Polevaya - Needham MA, US
Edward Domit - Westford MA, US
Andrew Baugher - Brighton MA, US
Patrick Burand - Winthrop MA, US

Nuvera Fuel Cells, LLC - Billerica MA

H01M 8/0258
H01M 8/1004
H01M 8/0232

An electrochemical cell stack is provided. The electrochemical cell stack has a plurality of electrochemical cells. Each electrochemical cell has a membrane electrode assembly which includes a cathode catalyst layer, an anode catalyst layer, and a polymer membrane interposed between the catalyst layer and the anode layer. Each electrochemical cell also has an anode plate and a cathode plate with the membrane electrode assembly interposed therebetween, and a cathode flow field positioned between the cathode plate and the cathode catalyst layer. The cathode flow field includes a porous structure having a plurality of pores having an average pore size. The plurality of electrochemical cells has a first electrochemical cell positioned at a first end of the electrochemical cell stack. The porous structure of the first electrochemical cell has an average pore size greater than the average pore size of the porous structures of the plurality of electrochemical cells. And, the porous structure of the first electrochemical cell has a flow resistance less than an average flow resistance of the porous structures of the plurality of electrochemical cells.

2019002, Jan 17, 2019

Sep 18, 2018

16/133804

- Billerica MA, US
Edward Domit - Westford MA, US
Duncan Lawrie - Girard PA, US

Nuvera Fuel Cells, LLC - Billerica MA

H01M 8/2475
C25B 9/20
H01M 8/248
C25B 1/12

In accordance with one embodiment, an electrochemical cell stack compression system may include an integral, hollow frame configured to contain a plurality of electrochemical cells arranged along an axis in a stack configuration. The frame may have a defined shape and may form a continuous border around a periphery of the electrochemical cell stack when inserted. The frame may be formed of a plurality of fibers.

2016031, Oct 27, 2016

Jul 6, 2016

15/203014

- Billerica MA, US
Benjamin Lunt - Tewksbury MA, US
Edward Domit - Westford MA, US
Roger Van Boeyen - Westford MA, US

H01M 8/0267
C25B 15/02
H01M 8/0228
H01M 8/04007
H01M 8/021

The present disclosure is directed towards the design of bipolar plates for use in conduction-cooled electrochemical cells. Heat generated during the operation of the cell is removed from the active area of the cell to the periphery of the cell via the one or more bipolar plates in the cell. The one or more bipolar plates are configured to function as heat sinks to collect heat from the active area of the cell and to conduct the heat to the periphery of the plate where the heat is removed by traditional heat transfer means. The boundary of the one or more bipolar plates can be provided with heat dissipation structures to facilitate removal of heat from the plates. To function as effective heat sinks, the thickness of the one or more bipolar plates can be determined based on the rate of heat generation in the cell during operation, the thermal conductivity (“k”) of the material selected to form the plate, and the desired temperature gradient in a direction orthogonal to the plate (“ΔT”).

2015003, Jan 29, 2015

Jul 29, 2014

14/445357

- BILLERICA MA, US
Edward DOMIT - Westford MA, US
Kevin BEVERAGE - Leominster MA, US
Scott BLANCHET - Chelmsford MA, US
John STANG - Columbus IN, US

NUVERA FUEL CELLS, INC. - BILLERICA MA

H01M 8/02
C25B 9/06

429463, 204252

An electrochemical cell includes a pair of bipolar plates and a membrane electrode assembly between the bipolar plates. The membrane electrode assembly comprises an anode compartment, a cathode compartment, and a proton exchange membrane disposed therebetween. The cell further includes a sealing surface formed in one of the pair of bipolar plates and a gasket located between the sealing surface and the proton exchange membrane. The gasket is configured to plastically deform to create a seal about one of the cathode compartment or the anode compartment. The sealing surface can include one or more protrusions.

2014025, Sep 11, 2014

Mar 5, 2014

14/198317

- Billerica MA, US
Edward Domit - Westford MA, US
Duncan Lawrie - Girard PA, US

Nuvera Fuel Cells, Inc. - Billerica MA

H01M 8/24

429469, 429535

In accordance with one embodiment, an electrochemical cell stack compression system may include an integral, hollow frame configured to contain a plurality of electrochemical cells arranged along an axis in a stack configuration. The frame may have a defined shape and may form a continuous border around a periphery of the electrochemical cell stack when inserted. The frame may be formed of a plurality of fibers.