WO2020097120A1 - Procédé et système de fabrication d'une pile à combustible - Google Patents

Procédé et système de fabrication d'une pile à combustible Download PDF

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Publication number
WO2020097120A1
WO2020097120A1 PCT/US2019/059925 US2019059925W WO2020097120A1 WO 2020097120 A1 WO2020097120 A1 WO 2020097120A1 US 2019059925 W US2019059925 W US 2019059925W WO 2020097120 A1 WO2020097120 A1 WO 2020097120A1
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WO
WIPO (PCT)
Prior art keywords
fuel cell
electrolyte
anode
additive manufacturing
cathode
Prior art date
Application number
PCT/US2019/059925
Other languages
English (en)
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Utility Global, Inc.
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Utility Global, Inc. filed Critical Utility Global, Inc.
Priority to EP19882250.4A priority Critical patent/EP3877180A4/fr
Priority claimed from US16/674,629 external-priority patent/US11557784B2/en
Publication of WO2020097120A1 publication Critical patent/WO2020097120A1/fr

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Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B33ADDITIVE MANUFACTURING TECHNOLOGY
    • B33YADDITIVE MANUFACTURING, i.e. MANUFACTURING OF THREE-DIMENSIONAL [3-D] OBJECTS BY ADDITIVE DEPOSITION, ADDITIVE AGGLOMERATION OR ADDITIVE LAYERING, e.g. BY 3-D PRINTING, STEREOLITHOGRAPHY OR SELECTIVE LASER SINTERING
    • B33Y80/00Products made by additive manufacturing
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M4/00Electrodes
    • H01M4/86Inert electrodes with catalytic activity, e.g. for fuel cells
    • H01M4/88Processes of manufacture
    • H01M4/8825Methods for deposition of the catalytic active composition
    • H01M4/8828Coating with slurry or ink
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M8/00Fuel cells; Manufacture thereof
    • H01M8/02Details
    • H01M8/0271Sealing or supporting means around electrodes, matrices or membranes
    • H01M8/0273Sealing or supporting means around electrodes, matrices or membranes with sealing or supporting means in the form of a frame
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M8/00Fuel cells; Manufacture thereof
    • H01M8/02Details
    • H01M8/0271Sealing or supporting means around electrodes, matrices or membranes
    • H01M8/028Sealing means characterised by their material
    • H01M8/0282Inorganic material
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M8/00Fuel cells; Manufacture thereof
    • H01M8/02Details
    • H01M8/0271Sealing or supporting means around electrodes, matrices or membranes
    • H01M8/0286Processes for forming seals
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M8/00Fuel cells; Manufacture thereof
    • H01M8/24Grouping of fuel cells, e.g. stacking of fuel cells
    • H01M8/2404Processes or apparatus for grouping fuel cells
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M8/00Fuel cells; Manufacture thereof
    • H01M8/10Fuel cells with solid electrolytes
    • H01M8/12Fuel cells with solid electrolytes operating at high temperature, e.g. with stabilised ZrO2 electrolyte
    • H01M2008/1293Fuel cells with solid oxide electrolytes
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M2300/00Electrolytes
    • H01M2300/0017Non-aqueous electrolytes
    • H01M2300/0065Solid electrolytes
    • H01M2300/0068Solid electrolytes inorganic
    • H01M2300/0071Oxides
    • H01M2300/0074Ion conductive at high temperature
    • H01M2300/0077Ion conductive at high temperature based on zirconium oxide
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M4/00Electrodes
    • H01M4/86Inert electrodes with catalytic activity, e.g. for fuel cells
    • H01M4/88Processes of manufacture
    • H01M4/8825Methods for deposition of the catalytic active composition
    • H01M4/8828Coating with slurry or ink
    • H01M4/8832Ink jet printing
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E60/00Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
    • Y02E60/30Hydrogen technology
    • Y02E60/50Fuel cells
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02PCLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
    • Y02P70/00Climate change mitigation technologies in the production process for final industrial or consumer products
    • Y02P70/50Manufacturing or production processes characterised by the final manufactured product

Definitions

  • This invention relates to manufacturing methods and systems. More particularly, this invention relates to methods and systems of manufacturing a fuel cell.
  • a fuel cell is an electrochemical apparatus that converts the chemical energy from a fuel into electricity through an electrochemical reaction. Sometimes, the heat generated by a fuel cell is also usable.
  • fuel cells There are many types of fuel cells.
  • PEMFCs proton-exchange membrane fuel cells
  • MEA membrane electrode assemblies
  • An ink of catalyst, carbon, and electrode are sprayed or painted onto the solid electrolyte and carbon paper is hot pressed on either side to protect the inside of the cell and also act as electrodes.
  • the most important part of the cell is the triple phase boundary where the electrolyte, catalyst, and reactants mix and thus where the cell reactions actually occur.
  • the membrane must not be electrically conductive so that the half reactions do not mix.
  • PEMFC is a good candidate for vehicle and other mobile applications of all sizes (e.g., mobile phones) because it is compact.
  • water management is crucial to performance: too much water will flood the membrane, too little will dry it; in both cases, power output will drop.
  • Water management is a difficult problem in PEM fuel cell systems, mainly because water in the membrane is attracted toward the cathode of the cell through polarization.
  • the platinum catalyst on the membrane is easily poisoned by carbon monoxide (CO level needs to be no more than one part per million).
  • CO level carbon monoxide
  • the membrane is also sensitive to things like metal ions, which can be introduced by corrosion of metallic bipolar plates, or metallic components in the fuel cell system, or from contaminants in the fuel and/or oxidant.
  • Solid oxide fuel cells are a different class of fuel cells that use a solid oxide material as the electrolyte.
  • SOFCs use a solid oxide electrolyte to conduct negative oxygen ions from the cathode to the anode.
  • the electrochemical oxidation of the oxygen ions with fuel e.g., hydrogen, carbon monoxide
  • Some SOFCs use proton conducting electrolytes (PC-SOFCs), which transport protons instead of oxygen ions through the electrolyte.
  • PC-SOFCs proton conducting electrolytes
  • SOFCs using oxygen ion conducting electrolytes have higher operating temperatures than PC-SOFCs.
  • SOFCs do not typically require expensive platinum catalyst material, which is typically necessary for lower temperature fuel cells such as proton- exchange membrane fuel ceils (PEMFCs), and are not vulnerable to carbon monoxide catalyst poisoning.
  • Solid oxide fuel cells have a wide variety of applications, such as auxiliary power units for homes and vehicles as well as stationary power generation units for data centers.
  • SOFCs comprise interconnects, which are placed between each individual cell so that the cells are connected in series and that the electricity generated by each cell is combined.
  • One category of SOFC is segmented-in-series (SIS) type SOFC, in which electrical current flow is parallel to the electrolyte in the lateral direction. Contrary to the SIS type SOFC, a different category of SOFC has electrical current flow perpendicular to the electrolyte in the lateral direction.
  • a method of making a fuel cell comprising: forming an anode using an additive manufacturing machine; forming a cathode using the additive manufacturing machine; and forming an electrolyte using the additive manufacturing machine, wherein the electrolyte is between the anode and the cathode.
  • electrical current flow is perpendicular to the electrolyte in the lateral direction when the fuel cell is in use.
  • a method of making a fuel cell comprises (a) producing an anode using an additive manufacturing machine (AMM); (b) creating an electrolyte using the additive manufacturing machine; (c) making a cathode using the additive manufacturing machine;
  • the fuel cell is a non-SIS type SOFC.
  • the method comprises assembling the anode, the electrolyte, and the cathode using the additive manufacturing machine. In an embodiment, the method comprises making at least one barrier layer using the additive manufacturing machine or making a catalyst layer using the additive manufacturing machine. In an embodiment, the method comprises making an interconnect using the additive manufacturing machine.
  • a first fuel cell is stacked with a second fuel cell such that the interconnect is in contact with surface A of an electrode of the first fuel cell, wherein surface A has an area larger than the average surface area of the electrode of the first fuel cell; and the interconnect is in contact with surface B of an electrode of the second fuel cell, wherein surface B has an area larger than the average surface area of the electrode of the second fuel cell, wherein the average surface area of the electrode is the total surface area of the electrode divided by the number of surfaces of the electrode.
  • the method comprises heating the anode, or the electrolyte, or the cathode, or combinations thereof. In an embodiment, heating is performed using
  • the EMR electromagnetic radiation
  • the EMR has a wavelength ranging from 10 to 1500 nm and the EMR has a minimum energy density of 0.1 Joule/cm 2 .
  • the EMR is provided by a xenon lamp.
  • peak wavelength is based on relative irradiance with respect to wavelength.
  • the EMR comprises UV light, near ultraviolet light, near infrared light, infrared light, visible light, laser, electron beam, microwave.
  • heating is performed in situ.
  • said additive manufacturing machine utilizes a multi-nozzle additive
  • said additive manufacturing machine utilizes a deposition method comprising material jetting, binder jetting, inkjet printing, aerosol jetting, or aerosol jet printing, vat photopolymerization, powder bed fusion, material extrusion, directed energy deposition, sheet lamination, ultrasonic inkjet printing, or combinations thereof.
  • an additive manufacturing machine comprising a chamber, wherein said chamber is configured to receive a material and configured to allow the material to be heated and reach a temperature of at least B00°C.
  • said material forms a portion of a fuel cell.
  • said chamber is configured to heat the material in situ.
  • said chamber is heated by electromagnetic radiation (EMR), or plasma, or hot fluid, or a heating element, or combinations thereof.
  • EMR electromagnetic radiation
  • the EMR is provided by a xenon lamp.
  • said chamber is configured to be filled with a fluid.
  • said fluid in the chamber is changed or replaced.
  • said fluid comprises an inert gas with no significant amount of oxygen.
  • said chamber is sealed, or enclosed, or open, or without top and side walls.
  • the additive manufacturing machine is configured to deploy material jetting, binder jetting, inkjet printing, aerosol jetting, or aerosol jet printing, vat photopolymerization, powder bed fusion, material extrusion, directed energy deposition, sheet lamination, ultrasonic inkjet printing, or combinations thereof.
  • a system comprising at least one deposition nozzle, an electromagnetic radiation (EMR) source, and a deposition receiver, wherein the deposition receiver is configured to receive both EMR exposure and deposition.
  • the deposition receiver is configured to receive both EMR exposure and deposition at the same location.
  • the deposition receiver is configured to move such that the receiver receives deposition for a first time period and to receive EMR exposure for second time period.
  • the EMR source comprises a xenon lamp.
  • the EMR source is a xenon lamp.
  • FIG. 1 illustrates a fuel cell comprising an anode, an electrolyte, and a cathode, according to an embodiment of this disclosure.
  • Figure 2 illustrates a fuel cell comprising an anode, an electrolyte, at least one barrier layer, and a cathode, according to an embodiment of this disclosure.
  • Figure 3 illustrates a fuel cell comprising an anode, a catalyst, an electrolyte, at least one barrier layer, and a cathode, according to an embodiment of this disclosure.
  • Figure 4 illustrates a fuel cell comprising an anode, a catalyst, an electrolyte, at least one barrier layer, a cathode, and an interconnect, according to an embodiment of this disclosure.
  • Figure 5 illustrates a fuel cell stack, according to an embodiment of this disclosure.
  • FIG. 6 illustrates a method and system of integrated deposition and heating using electromagnetic radiation (EMR), according to an embodiment of this disclosure.
  • EMR electromagnetic radiation
  • Figure 7 illustrates SRTs of a first composition and a second composition as a function of temperature, according to an embodiment of this disclosure.
  • Figure 8 illustrates a process flow for forming and heating at least a portion of a fuel cell, according to an embodiment of this disclosure.
  • Figure 9 illustrates maximum height profile roughness, according to an embodiment of this disclosure.
  • Figure 10 is a scanning electron microscopy image (side view) illustrating an electrolyte (YSZ) printed and sintered on an electrode (NiO-YSZ), according to an embodiment of this disclosure.
  • FIG 11A illustrates a perspective view of a fuel cell cartridge (FCC), according to an embodiment of this disclosure.
  • FIG. 11B illustrates cross-sectional views of a fuel cell cartridge (FCC), according to an embodiment of this disclosure.
  • FIG. 11C illustrates top view and bottom view of a fuel cell cartridge (FCC), according to an embodiment of this disclosure.
  • compositions and materials are used interchangeably unless otherwise specified. Each composition/material may have multiple elements, phases, and components. Heating as used herein refers to actively adding energy to the compositions or materials. In situ in this disclosure refers to the treatment (e.g., heating) process being performed either at the same location or in the same device of the forming process of the compositions or
  • the deposition process and the heating process are performed in the same device and at the same location, in other words, without changing the device and without changing the location within the device.
  • the deposition process and the heating process are performed in the same device at different locations, which is also considered in situ.
  • AM additive manufacturing
  • AM is also referred as additive fabrication, additive processes, additive techniques, additive layer manufacturing, layer manufacturing, and freeform fabrication.
  • Some examples of AM are extrusion, photopolymerization, powder bed fusion, material jetting, binder jetting, directed energy deposition, lamination, direct metal laser sintering (DMLS), selective laser sintering (SLS), selective laser melting (SLM), directed energy deposition (DED), laser metal deposition (LMD), electron beam (EBAM), and metal binder jetting.
  • DMLS direct metal laser sintering
  • SLS selective laser sintering
  • SLM selective laser melting
  • DED directed energy deposition
  • LMD laser metal deposition
  • EBAM electron beam
  • a 3D printer is a type of AM machine (AMM).
  • An inkjet printer or ultrasonic inkjet printer are also AMM's.
  • strain rate tensor or "SRT” is meant to refer to the rate of change of the strain of a material in the vicinity of a certain point and at a certain time. It can be defined as the derivative of the strain tensor with respect to time. When SRTs or difference of SRTs are compared in this disclosure, it is the magnitude that is being used.
  • lateral refers to the direction that is perpendicular to the stacking direction of the layers in a non-SIS type fuel cell.
  • lateral direction refers to the direction that is perpendicular to the stacking direction of the layers in a fuel cell or the stacking direction of the slices to form an object during deposition.
  • Lateral also refers to the direction that is the spread of deposition process.
  • Syngas i.e., synthesis gas in this disclosure refers to a mixture consisting primarily of hydrogen, carbon monoxide, and carbon dioxide.
  • absorbance is a measure of the capacity of a substance to absorb electromagnetic radiation (EMR) of a wavelength.
  • a method of making a fuel cell comprises using only one additive manufacturing machine (AMM) to manufacture a fuel cell, wherein the fuel cell comprises an anode, electrolyte, and a cathode.
  • AMM additive manufacturing machine
  • the fuel cell comprises at least one barrier layer, for example, between the electrolyte and the cathode, or between the electrolyte and the cathode, or both.
  • the at least one barrier layer is also preferably made by the same single additive manufacturing machine.
  • the additive manufacturing machine also produces an interconnect and assembles the interconnect with the anode, the cathode, the barrier layer(s), and the electrolyte.
  • the interconnect, the anode, the electrolyte, and the cathode are formed layer on layer, for example, printed layer on layer. It is important to note that, within the scope of the invention, the order of forming these layers can be varied. In other words, either the anode or the cathode can be formed before the other. Naturally, the electrolyte is formed so that it is between the anode and the cathode.
  • the barrier layer(s), catalyst layer(s) and interconnect(s) are formed so as to lie in the appropriate position within the fuel cell to perform their functions.
  • each of the interconnect, the anode, the electrolyte, and the cathode has six faces.
  • the anode is printed on the interconnect and is in contact with the interconnect;
  • the electrolyte is printed on the anode and is in contact with the anode;
  • the cathode is printed on the electrolyte and is in contact with the electrolyte.
  • Each print is sintered, for example, using EMR.
  • the assembling process and the forming process are simultaneous, which is not possible with conventional methods. Moreovoer, with the preferred embodiment, the needed electrical contact and gas tightness are also achieved at the same time.
  • conventional fuel cell assembling processes are required to accomplish this via pressing or compression of the fuel cell components or layers. The pressing or compression process can cause cracks in the fuel cell layers that are undesirable.
  • the single AMM makes a first fuel cell, wherein the fuel cell comprises the anode, the electrolyte, the cathode, the at least one barrier layer, and the interconnect.
  • the single AMM makes a second fuel cell.
  • the single AMM assembles the first fuel cell with the second fuel cell to form a fuel cell stack.
  • the production using AMM is repeated as many times as desired; and a fuel cell stack is assembled using the AMM.
  • the various layers of the fuel cell are produced by the AMM above ambient temperature, for example, above 100 °C, from 100 °C to 500 °C, from 100 °C to 300 °C.
  • the fuel cell or fuel cell stack is heated after it is formed/assembled. In an embodiment, the fuel cell or fuel cell stack is heated at a temperature above 500 °C. In an embodiment, the fuel cell or fuel cell stack is heated at a temperature from 500 °C to 1500 °C.
  • the AMM comprises a chamber where the manufacturing of fuel cells takes place. This chamber is able to withstand high temperature to enable the production of the fuel cells. In an embodiment, this high temperature is at least 300 °C. In an embodiment, this high temperature is at least 500 °C. In an embodiment, this high
  • this high temperature is at least 1500 °C.
  • this chamber also enables heating of the fuel cells to take place in the chamber.
  • Various heating methods are applied, such as laser heating/curing, electromagnetic wave heating, hot fluid heating, or heating element associated with the chamber.
  • the heating element may be a heating surface or a heating coil or a heating rod and is associated with the chamber such that the content in the chamber is heated to the desired temperature range.
  • the chamber of the AMM is able to apply pressure to the fuel cell(s) inside, for example, via a moving element (e.g., a moving stamp or plunger).
  • the chamber of the AMM is able to withstand pressure.
  • the chamber can be pressurized by a fluid and de-pressurized as desired.
  • the fluid in the chamber can also be changed/replaced as needed.
  • the fuel cell or fuel cell stack is heated using EMR.
  • the fuel cell or fuel cell stack is heated using oven curing.
  • the laser beam is expanded (for example, by the use of one or more mirrors) to create a heating zone with uniform power density.
  • each layer of the fuel cell is EMR cured separately.
  • a combination of fuel cell layers is EMR cured separately, for example, a combination of the anode, the electrolyte, and the cathode layers.
  • a first fuel cell is EMR cured, assembled with a second fuel cell, and then the second fuel cell is EMR cured.
  • a first fuel cell is assembled with a second fuel cell, and then the first fuel cell and the second fuel cell are EMR cured separately.
  • a first fuel cell is assembled with a second fuel cell to form a fuel cell stack, and then the fuel cell stack is EMR cured.
  • the sequence of laser heating/curing and assembling is applicable to all other heating methods.
  • the AMM produces each layer of a multiplicity of fuel cells simultaneously. In an embodiment, the AMM assembles each layer of a multiplicity of fuel cells simultaneously. In an embodiment, heating of each layer or heating of a combination of layers of a multiplicity of fuel cells takes place simultaneously. All the discussion and all the features herein for a fuel cell or a fuel cell stack are applicable to the production, assembling, and heating of the multiplicity of fuel cells. In an embodiment, a multiplicity of fuel cells is 20 or more. In an embodiment, a multiplicity of fuel cells is 50 or more. In an embodiment, a multiplicity of fuel cells is 80 or more. In an embodiment, a multiplicity of fuel cells is 100 or more. In an embodiment, a multiplicity of fuel cells is 500 or more.
  • a multiplicity of fuel cells is 800 or more. In an embodiment, a multiplicity of fuel cells is 1000 or more. In an embodiment, a multiplicity of fuel cells is 5000 or more. In an embodiment, a multiplicity of fuel cells is 10,000 or more.
  • the treatment process comprises exposing a substrate to a source of electromagnetic radiation (EMR).
  • EMR electromagnetic radiation
  • the EMR treats a substrate having a first material.
  • the EMR has a wavelength ranging from 10 to 1500 nm.
  • the EMR has a minimum energy density of 0.1 Joule/cm 2 .
  • the EMR has a burst frequency of 1-1000 Hz or 10-1000 Hz.
  • the EMR has an exposure distance of no greater than 50 mm.
  • the EMR has an exposure duration no less than 0.1 ms or 1 ms.
  • the EMR is applied with a capacitor voltage of no less than 100V. For example, a single pulse of EMR is applied with an exposure distance of about 10 mm and an exposure duration of 5-20 ms.
  • SOFCs solid oxide fuel cells
  • the invention is a method of making a fuel cell comprising (a) producing an anode using an additive manufacturing machine (AMM); (b) creating an electrolyte using the AMM; and (c) making a cathode using the AMM.
  • AMM additive manufacturing machine
  • the anode, the electrolyte, and the cathode are assembled into a fuel cell utilizing the AMM.
  • the fuel cell is formed using only the AMM.
  • steps (a), (b), and (c) exclude tape casting and exclude screen printing.
  • the method excludes compression in assembling.
  • the layers are deposited one on top of another and as such assembling is accomplished at the same time as deposition.
  • the method of this disclosure is useful in making planar fuel cells.
  • the method of this disclosure is useful in making fuel cells, wherein electrical current flow is perpendicular to the electrolyte in the lateral direction when the fuel cell is in use.
  • the method comprises making at least one barrier layer using the AMM.
  • the at least one barrier layer is used between the electrolyte and the cathode or between the electrolyte and the anode or both.
  • the at least one barrier layer is assembled with the anode, the electrolyte, and the cathode using the AMM.
  • no barrier layer is utilized in the fuel cell.
  • the method comprises making an interconnect using the AMM.
  • the interconnect is assembled with the anode, the electrolyte, and the cathode using the AMM.
  • the AMM forms a catalyst and incorporates said catalyst into the fuel cell.
  • the anode, the electrolyte, the cathode, and the interconnect are made at a temperature above 100 °C.
  • the method comprises heating the
  • the fuel cell comprises the anode, the electrolyte, the cathode, the interconnect, and optionally at least one barrier layer.
  • the fuel cell comprises a catalyst.
  • the method comprises heating the fuel cell to a temperature above 500 °C.
  • the fuel cell is heated using EMR or oven curing.
  • the AMM utilizes a multi-nozzle additive manufacturing method.
  • the multi-nozzle additive manufacturing method comprises nanoparticle jetting.
  • a first nozzle delivers a first material.
  • a second nozzle delivers a second material.
  • a third nozzle delivers a third material.
  • particles of a fourth material are placed in contact with a partially constructed fuel cell and bonded to the partially constructed fuel cell using a laser
  • the anode, or the cathode, or the electrolyte comprises a first, second, third, or fourth material.
  • the AMM performs multiple additive manufacturing techniques.
  • the additive manufacturing techniques comprise extrusion,
  • additive manufacturing is a deposition technique comprising material jetting, binder jetting, inkjet printing, aerosol jetting, or aerosol jet printing, vat photopolymerization, powder bed fusion, material extrusion, directed energy deposition, sheet lamination, ultrasonic inkjet printing, or combinations thereof.
  • AMM additive manufacturing machine
  • anode, the electrolyte, the cathode, and the interconnect form a first fuel cell; (e) repeating steps (a)-(d) to make a second fuel cell; and (f) assembling the first fuel cell and the second fuel cell into a fuel cell stack.
  • the first fuel cell and the second fuel cell are formed from the anode, the electrolyte, the cathode, and the interconnect utilizing the AMM.
  • the fuel cell stack is formed using only the AMM.
  • steps (a)-(f) exclude tape casting and exclude screen printing.
  • the method comprises making at least one barrier layer using the AMM.
  • the at least one barrier layer is used between the electrolyte and the cathode or between the electrolyte and the anode or both for the first fuel cell and the second fuel cell.
  • steps (a)-(d) are performed at a temperature above 100 °C. In an embodiment, steps (a)-(d) are performed at a temperature from 100 °C to 500 °C. In an embodiment, the AMM makes a catalyst and incorporates said catalyst into the fuel cell stack.
  • the method comprises heating the fuel cell stack.
  • the method comprises heating the fuel cell stack to a temperature above 500 °C.
  • the fuel cell stack is heated using EMR or oven curing.
  • the laser has a laser beam, wherein said laser beam is expanded to create a heating zone with uniform power density.
  • the laser beam is expanded by the use of one or more mirrors.
  • each layer of the fuel cell is EMR cured separately.
  • a combination of fuel cell layers is EMR cured separately.
  • the first fuel cell is EMR cured, assembled with the second fuel cell, and then the second fuel cell is EMR cured.
  • the first fuel cell is assembled with the second fuel cell, and then the first fuel cell and the second fuel cell are EMR cured separately.
  • the first fuel cell and the second fuel cell are EMR cured separately, and then the first fuel cell is assembled with the second fuel cell to form a fuel cell stack. In an embodiment, the first fuel cell is assembled with the second fuel cell to form a fuel cell stack, and then the fuel cell stack is EMR cured.
  • a method of making a multiplicity of fuel cells comprising (a) producing a multiplicity of anodes simultaneously using an additive manufacturing machine (AMM); (b) creating a multiplicity of electrolytes using the AMM simultaneously; and (c) making a multiplicity of cathodes using the AMM simultaneously.
  • AMM additive manufacturing machine
  • the anodes, the electrolytes, and the cathodes are assembled into fuel cells utilizing the AMM simultaneously.
  • the fuel cells are formed using only the AMM.
  • the method comprises making at least one barrier layer using the AMM for each of the multiplicity of fuel cells simultaneously.
  • said at least one barrier layer is used between the electrolyte and the cathode or between the electrolyte and the anode or both.
  • said at least one barrier layer is assembled with the anode, the electrolyte, and the cathode using the AMM for each fuel cell.
  • the method comprises making an interconnect using the AMM for each of the multiplicity of fuel cells simultaneously.
  • said interconnect is assembled with the anode, the electrolyte, and the cathode using the AMM for each fuel cell.
  • the AMM forms a catalyst for each of the multiplicity of fuel cells
  • the multiplicity of fuel cells is 20 fuel cells or more.
  • the AMM uses different nozzles to jet/print different materials at the same time.
  • a first nozzle makes an anode for fuel cell 1
  • a second nozzle makes a cathode for fuel cell 2
  • a third nozzle makes an electrolyte for fuel cell 3, at the same time.
  • a first nozzle makes an anode for fuel cell 1
  • a second nozzle makes a cathode for fuel cell 2
  • a third nozzle makes an electrolyte for fuel cell 3
  • a fourth nozzle makes an interconnect for fuel cell 4, at the same time.
  • an additive manufacturing machine comprising a chamber, wherein manufacturing of fuel cells takes place, wherein said chamber is able to withstand a temperature of at least 300 °C.
  • said chamber enables production of the fuel cells.
  • said chamber enables heating of the fuel cells in situ.
  • said chamber is heated by laser, or electromagnetic waves/electromagnetic radiation (EMR), or hot fluid, or heating element associated with the chamber, or combinations thereof.
  • said heating element comprises a heating surface or a heating coil or a heating rod.
  • said chamber is configured to apply pressure to the fuel cells inside. In an embodiment, the pressure is applied via a moving element associated with the chamber. In an embodiment, said moving element is a moving stamp or plunger. In an embodiment, said chamber is configured to withstand pressure. In an embodiment, said chamber is configured to be pressurized by a fluid or de-pressurized. In an embodiment, said fluid in the chamber is changed or replaced.
  • the chamber is enclosed. In some cases, the chamber is sealed. In some cases, the chamber is open. In some cases, the chamber is a platform without top and side walls.
  • 601 schematically represents deposition nozzles or material jetting nozzles
  • 602 represents the EMR source, e.g., xenon lamp
  • 603 represents the object being formed
  • 604 represents the chamber as a part of an AMM.
  • the chamber or receiver 604 is configured to receive both deposition from nozzles and radiation from an EMR source.
  • deposition nozzles 601 are movable.
  • the chamber or receiver 604 is movable.
  • the EMR source 602 is movable.
  • the object comprises a catalyst, a catalyst support, a catalyst composite, an anode, a cathode, an electrolyte, an electrode, an
  • interconnect a seal, a fuel cell, an electrochemical gas producer, an electrolyser, an
  • electrochemical compressor a reactor, a heat exchanger, a vessel, or combinations thereof.
  • Additive Manufacturing techniques suitable for this disclosure comprise extrusion, photopolymerization, powder bed fusion, material jetting, binder jetting, directed energy deposition, and lamination.
  • Additive Manufacturing is extrusion additive manufacturing. Extrusion additive manufacturing involves the spatially controlled deposition of material (e.g., thermoplastics). It is also referred to as fused filament fabrication (FFF) or fused deposition modeling (FDM) in this disclosure.
  • FFF fused filament fabrication
  • FDM fused deposition modeling
  • Additive Manufacturing is photopolymerization, i.e., photopolymerization
  • SLA stereolithography
  • Additive Manufacturing is Powder bed fusion (PBF).
  • PBF AM processes build objects by melting powdered feedstock, such as a polymer or metal. PBF processes begin by spreading a thin layer of powder across the build area. Cross sections are then melted a layer at a time, most often using a laser, electron beam, or intense infrared lamps.
  • PBF of metals is selective laser melting (SLM) or electron beam melting (EBM).
  • PBF of polymers is selective laser sintering (SLS).
  • SLS systems print thermoplastic polymer materials, polymer composites, or ceramics.
  • SLM systems are suitable for a variety of pure metals and alloys, wherein the alloys are compatible with the rapid solidification that occurs in SLM.
  • Additive Manufacturing is material jetting.
  • Additive manufacturing by material jetting is accomplished by depositing small drops (or droplets) of material, with spatial control.
  • material jetting is performed three dimensionally (3D) or two dimensionally (2D) or both.
  • 3D jetting is accomplished layer by layer.
  • print preparation converts the computer-aided design (CAD), along with specifications of material composition, color, and other variables to the printing instructions for each layer.
  • Binder jetting AM involves inkjet deposition of a liquid binder onto a powder bed.
  • binder jetting combines physics of other AM processes: spreading of powder to make the powder bed (analogous to SLS/SLM), and inkjet printing.
  • Additive Manufacturing is directed energy deposition (DED).
  • the DED process uses a directed flow of powder or a wire feed, along with an energy intensive source such as laser, electric arc, or electron beam.
  • DED is a direct-write process, wherein the location of material deposition is determined by movement of the deposition head, which allows large metal structures to be built without the constraints of a powder bed.
  • Additive Manufacturing is Lamination AM, or Laminated Object Manufacturing (LOM).
  • LOM Laminated Object Manufacturing
  • consecutive layers of sheet material are
  • the method of this disclosure manufactures a fuel cell or a fuel cell stack using one AMM.
  • the AMM of this disclosure preferably performs both extrusion and ink jetting to manufacture a fuel cell or fuel cell stack.
  • Extrusion is used to manufacture thicker layers of a fuel cell, such as, the anode and/or the cathode.
  • Ink jetting is used to manufacture thin layers of a fuel cell.
  • Ink jetting is preferably used to form the electrolyte.
  • the AMM operates at temperature ranges sufficient to enable curing in the AMM itself. Such temperature ranges are 100 °C or above, such as 100 °C - S00 °C or 100 °C - 500 °C.
  • all the layers of a fuel cell are formed and assembled via printing.
  • the interconnect is made into an ink form comprising a solvent and particles (e.g., nanoparticles).
  • aqueous inks There are two categories of ink formulations - aqueous inks and non-aqueous inks.
  • the aqueous ink comprises an aqueous solvent (e.g., water, deionized water), particles, a dispersant, and a surfactant.
  • the aqueous ink comprises an aqueous solvent (e.g., water, deionized water), particles, a dispersant, a surfactant, but no polymeric binder.
  • the aqueous ink optionally comprises a co-solvent, such as an organic miscible solvent (methanol, ethanol, isopropyl alcohol).
  • a co-solvent such as an organic miscible solvent (methanol, ethanol, isopropyl alcohol).
  • co-solvents preferably have a lower boiling point than water.
  • the dispersant is an electrostatic dispersant, a steric dispersant, an ionic dispersant, a non-ionic dispersant, or a combination thereof.
  • the surfactant is preferably non-ionic, such as an alcohol alkoxylate, an alcohol ethoxylate.
  • the non-aqueous ink comprises an organic solvent (e.g., methanol, ethanol, isopropyl alcohol, butanol) and particles.
  • CGO powder is mixed with water to form an aqueous ink with a dispersant added and a surfactant added but with no polymeric binder added.
  • the CGO fraction based on mass is in the range of from 10 wt% to 25 wt%.
  • CGO powder is mixed with ethanol to form a non-aqueous ink with polyvinyl butaryl added.
  • the CGO fraction based on mass is in the range of from 3 wt% to 30 wt%.
  • LSCF is mixed with n-butanol or ethanol to form a non-aqueous ink with polyvinyl butaryl added.
  • the LSCF fraction based on mass is in the range of from 10 wt% to 40 wt%.
  • YSZ particles are mixed with water to form an aqueous ink with a dispersant added and a surfactant added but with no polymeric binder added.
  • the YSZ fraction based on mass is in the range of from 3 wt% to 40 wt%.
  • NiO particles are mixed with water to form an aqueous ink with a dispersant added and a surfactant added but with no polymeric binder added.
  • the NiO fraction based on mass is in the range of from 5 wt% to 25 wt%.
  • LSCF or LSM particles are dissolved in a solvent, wherein the solvent is water or an alcohol (e.g., butanol) or a mixture of alcohols. Organic solvents other than alcohols may also be used.
  • LSCF is deposited (e.g., printed) into a layer.
  • a xenon lamp irradiates the LSCF layer with EMR to sinter the LSCF.
  • the flash lamp is a 10 kW unit applied at a voltage of 400V and a frequency of 10 Hz for a total exposure duration of 1000 ms.
  • YSZ particles are mixed with a solvent, wherein the solvent is water (e.g., de-ionized water) (e.g., de-ionized water) or an alcohol (e.g., butanol) or a mixture of alcohols.
  • the solvent is water (e.g., de-ionized water) (e.g., de-ionized water) or an alcohol (e.g., butanol) or a mixture of alcohols.
  • Organic solvents other than alcohols may also be used.
  • the solvent may include water (e.g., de-ionized water), organic solvents (e.g. mono-, di-, or tri ethylene glycols or higher ethylene glycols, propylene glycol, 1,4-butanediol or ethers of such glycols, thiodiglycol, glycerol and ethers and esters thereof, polyglycerol, mono-, di-, and tri ethanolamine, propanolamine, N,N-dimethylformamide, dimethyl sulfoxide,
  • water e.g., de-ionized water
  • organic solvents e.g. mono-, di-, or tri ethylene glycols or higher ethylene glycols, propylene glycol, 1,4-butanediol or ethers of such glycols, thiodiglycol, glycerol and ethers and esters thereof, polyglycerol, mono-, di-, and tri ethanolamine, propanolamine, N
  • CGO particles are dissolved in a solvent, wherein the solvent is water (e.g., de-ionized water) or an alcohol (e.g., butanol) or a mixture of alcohols. Organic solvents other than alcohols may also be used.
  • the solvent is water (e.g., de-ionized water) or an alcohol (e.g., butanol) or a mixture of alcohols.
  • Organic solvents other than alcohols may also be used.
  • CGO is used as barrier layer for LSCF.
  • YSZ may also be used as a barrier layer for LSM.
  • no polymeric binder is added to the aqueous inks.
  • the treatment process comprises exposing a substrate to a source of electromagnetic radiation (EMR).
  • EMR electromagnetic radiation
  • the EMR treats a substrate having a first material.
  • the EMR has a wavelength ranging from 10 to 1500 nm. The wavelengths of the EMR utilized depend on the material being sintered. The exposure distance and the slice thickness are also adjusted to achieve desired printing and sintering results for different materials.
  • the EMR has a minimum energy density of 0.1 Joule/cm 2 .
  • the EMR has a burst frequency of 10 4 -1000 Hz or 1-1000 Hz or 10-1000 Hz.
  • the EMR has an exposure distance of no greater than 50 mm.
  • the EMR has an exposure duration no less than 0.1 ms or 1 ms.
  • the EMR is applied with a capacitor voltage of no less than 100V. For example, a single pulse of EMR is applied with an exposure distance of about 10 mm and an exposure duration of 5-20 ms.
  • multiple pulses of EMR are applied at a burst frequency of 100Hz with an exposure distance of about 10 mm and an exposure duration of 5-20 ms.
  • the EMR is performed in one exposure.
  • the EMR is performed in no greater than 10 exposures, or no greater than 100 exposures, or no greater than 1000 exposures, or no greater than 10,000 exposures.
  • metals and ceramics are sintered almost instantly (milliseconds for «10 microns) using pulsed light.
  • the sintering temperature is controlled to be in the range of from 100 °C to 2000 °C.
  • the sintering temperature is tailored as a function of depth.
  • the surface temperature is 1000 °C and the sub-surface is kept at 100 °C, wherein the sub surface is 100 microns below the surface.
  • the material suitable for this treatment process includes Yttria-stabilized zirconia (YSZ), 8YSZ (8mol% YSZ powder), Yttirum, Zirconium, gadolinia-doped ceria (GDC or CGO), Samaria-doped ceria (SDC), Scandia-stabilized zirconia (SSZ), Lanthanum strontium manganite (LSM), Lanthanum Strontium Cobalt Ferrite (LSCF), Lanthanum Strontium Cobaltite (LSC), Lanthanum Strontium Gallium Magnesium Oxide (LSGM), Nickel, NiO, NiO-YSZ, Cu-CGO, Cu 2 0, CuO, Cerium, copper, silver, crofer, steel, lanthanum chromite, doped lanthanum chromite, ferritic steel, stainless steel, or combinations thereof.
  • YSZ Yttria-stabilized zirconia
  • 8YSZ 8mol% Y
  • This treatment process is applicable in the manufacturing process of a fuel cell.
  • a layer of a fuel cell (anode, cathode, electrolyte, seal, catalyst) is treated using the process of this disclosure to be heated, cured, sintered, sealed, alloyed, foamed, evaporated, restructured, dried, or annealed.
  • a portion of a layer of a fuel cell (anode, cathode, electrolyte, seal, catalyst) is treated using the process of this disclosure to be heated, cured, sintered, sealed, alloyed, foamed, evaporated, restructured, dried, or annealed.
  • a combination of layers of a fuel cell is treated using the process of this disclosure to be heated, cured, sintered, sealed, alloyed, foamed, evaporated, restructured, dried, or annealed, wherein the layers may be a complete layer or a partial layer.
  • the treatment process is sintering and is accomplished by EMR.
  • the treatment process of this disclosure is preferably rapid with the treatment duration varied from microseconds to milliseconds.
  • the treatment duration is accurately controlled.
  • the treatment process of this disclosure produces fuel cell layers that have no crack or have minimal cracking.
  • the treatment process of this disclosure controls the power density or energy density in the treatment volume of the material being treated.
  • the treatment volume is accurately controlled.
  • the treatment process of this disclosure provides the same energy density or different energy densities in a treatment volume.
  • the treatment process of this disclosure provides the same treatment duration or different treatment durations in a treatment volume.
  • the treatment process of this disclosure provides simultaneous treatment for one or more treatment volumes.
  • the treatment process of this disclosure provides simultaneous treatment for one or more fuel cell layers or partial layers or combination of layers.
  • the treatment volume is varied by changing the treatment depth.
  • a first portion of a treatment volume is treated by electromagnetic radiation of a first wavelength; a second portion of the treatment volume is treated by electromagnetic radiation of a second wavelength.
  • the first wavelength is the same as the second wavelength.
  • the first wavelength is different from the second wavelength.
  • the first portion of a treatment volume has a different energy density from the second portion of the treatment volume.
  • the first portion of a treatment volume has a different treatment duration from the second portion of the treatment volume.
  • the EMR has a broad emission spectrum so that the desired effects are achieved for a wide range of materials having different absorption characteristics.
  • absorption of electromagnetic radiation refers to the process, wherein the energy of a photon is taken up by matter, such as the electrons of an atom.
  • the electromagnetic energy is transformed into internal energy of the absorber, for example, thermal energy.
  • the EMR spectrum extends from the deep ultraviolet (UV) range to the near infrared (IR) range, with peak pulse powers at 220 nm wavelength.
  • the power of such EMR is on the order of Megawatts.
  • Such EMR sources perform tasks such as breaking chemical bonds, sintering, ablating or sterilizing.
  • the EMR has an energy density of no less than 0.1, 1, or 10
  • the EMR has a power output of no less than 1 watt (W), 10 W, 100 W, 1000 W.
  • the EMR delivers power to the substrate of no less than 1 W, 10 W, 100 W, or 1000 W.
  • such EMR exposure heats the material in the substrate.
  • the EMR has a range or a spectrum of different wavelengths.
  • the treated substrate is at least a portion of an anode, cathode, electrolyte, catalyst, barrier layer, or interconnect of a fuel cell.
  • the peak wavelength of the EMR is between 50 and 550 nm or between 100 and 300 nm. In an embodiment, the wavelength of the EMR is between 50 and 550 nm or between 100 and 300 nm. In an embodiment, the absorption of at least a portion of the substrate for at least one frequency of the EMR between 10 and 1500 nm is no less than 30% or no less than 50%. In an embodiment, the absorption of at least a portion of the substrate for at least one frequency between 50 and 550 nm is no less than 30% or no less than 50%. In an embodiment, the absorption of at least a portion of the substrate for at least one frequency between 100 and 300 nm is no less than 30% or no less than 50%.
  • Sintering is the process of compacting and forming a solid mass of material by heat or pressure without melting it to the point of liquefaction.
  • the substrate under EMR exposure is sintered but not melted.
  • the EMR is UV light, near ultraviolet light, near infrared light, infrared light, visible light, laser, electron beam, microwave.
  • the substrate is exposed to the EMR for no less than 1 microsecond, no less than 1 millisecond.
  • the substrate is exposed to the EMR for less than 1 second at a time or less than 10 seconds at a time.
  • the substrate is exposed to the EMR for less than 1 second or less than 10 seconds.
  • the substrate is exposed to the EMR repeatedly, for example, more than 1 time, more than 3 times, more than 10 times.
  • the substrate is distanced from the source of the EMR for less than 50 cm, less than 10 cm, less than 1 cm, or less than 1 mm.
  • a second material is added to or placed on to the first material.
  • the second material is the same as the first material.
  • the second material is exposed to the EMR.
  • a third material is added.
  • the third material is exposed to the EMR.
  • the first material comprises YSZ, 8YSZ, Yttirum, Zirconium, GDC, SDC, LSM, LSCF, LSC, Nickel, NiO, Cerium.
  • the second material comprises graphite.
  • the electrolyte, anode, or cathode comprises a second material.
  • the volume fraction of the second material in the electrolyte, anode, or cathode is less than 20%, 10%, 3%, or 1%.
  • the absorption rate of the second material for at least one frequency e.g., between 10 and 1500 nm or between 100 and 300 nm or between 50 and 550 nm) is greater than 30% or greater than 50%.
  • one or a combination of parameters are controlled, wherein such parameters include distance between the EMR source and the substrate, the energy density of the EMR, the spectrum of the EMR, the voltage of the EMR, the duration of exposure, the burst frequency, and the number of EMR exposures.
  • these parameters are controlled to minimize the formation of cracks in the substrate.
  • the EMR energy is delivered to a surface area of no less than 1 mm 2 , or no less than 1 cm 2 , or no less than 10 cm 2 , or no less than 100 cm 2 .
  • at least a portion of an adjacent material is heated at least in part by conduction of heat from the first material.
  • the layers of the fuel cell e.g., anode, cathode, electrolyte
  • they are no greater than 30 microns, no greater than 10 microns, or no greater than 1 micron.
  • the first material of the substrate is in the form of a powder, sol gel, colloidal suspension, hybrid solution, or sintered material.
  • the second material may be added by vapor deposition.
  • the second material coats the first material.
  • the second material reacts with light, e.g. focused light, as by a laser, and sinters or anneals with the first material.
  • the preferred treatment process of this disclosure enables rapid manufacturing of fuel cells by eliminating traditional, costly, time consuming, expensive sintering processes and replacing them with rapid, in-situ methods that allow continuous manufacturing of the layers of a fuel cell in a single machine if desired. This process also shortens sintering time from hours and days to seconds or milliseconds or even microseconds.
  • this treatment method is used in combination with
  • This preferred treatment method enables tailored and controlled heating by tuning EMR characteristics (such as, wavelengths, energy density, burst frequency, and exposure duration) combined with controlling thicknesses of the layers of the substrate and heat conduction into adjacent layers to allow each layer to sinter, anneal, or cure at each desired target
  • This process enables more uniform energy application, decreases or eliminates cracking, which improves electrolyte performance.
  • the substrate treated with this preferred process also has less thermal stress due to more uniform heating.
  • the preferred method comprises depositing a composition on a substrate slice by slice to form an object; heating in situ the object using electromagnetic radiation (EMR); wherein said composition comprises a first material and a second material, wherein the second material has a higher absorbance of the radiation than the first material.
  • heating causes an effect comprising drying, curing, sintering, annealing, sealing, alloying, evaporating, restructuring, foaming, or combinations thereof.
  • the preferred effect is sintering.
  • the EMR has a wavelength ranging from 10 to 1500 nm and the EMR has a minimum energy density of 0.1 Joule/cm 2 .
  • peak wavelength is on the basis of relative irradiance with respect to wavelength.
  • the EMR comprises UV light, near ultraviolet light, near infrared light, infrared light, visible light, laser, electron beam.
  • Figure 6 illustrates an object on a substrate formed by deposition nozzles and EMR for heating in situ, according to the preferred embodiment of this disclosure.
  • the first material comprises YSZ, SSZ, CGO, SDC, NiO-YSZ, LSM-YSZ, CGO-LSCF, doped lanthanum chromite, stainless steel, or combinations thereof.
  • the second material comprises carbon, nickel oxide, nickel, silver, copper, CGO, SDC, NiO-YSZ, NiO-SSZ, LSCF, LSM, doped lanthanum chromite ferritic steels, or combinations thereof.
  • said object comprises a catalyst, a catalyst support, a catalyst composite, an anode, a cathode, an electrolyte, an electrode, an interconnect, a seal, a fuel cell, an electrochemical gas producer, an electrolyser, an electrochemical compressor, a reactor, a heat exchanger, a vessel, or combinations thereof.
  • the second material is a deposited in the same slice as the first material.
  • the second material is a deposited in a slice adjacent another slice that contains the first material.
  • said heating removes at least a portion of the second material.
  • said removing leaves minimal residue of the portion of the second material.
  • this step leaves minimal residue of the portion of the second material, which is to say that there is no significant residue that would interfere with the subsequent steps in the process or the operation of the device being constructed. More preferably, this leaves no measurable reside of the second material.
  • the second material adds thermal energy to the first material during heating.
  • the second material has a radiation absorption that is at least 5 times that of the first material; preferably the second material has a radiation absorption that is at least 10 times that of the first material; more preferably the second material has a radiation absorption that is at least 50 times that of the first material; most preferably the second material has a radiation absorption that is at least 100 times that of the first material.
  • the second material has a peak absorbance wavelength no less than 200 nm, or no less than 250 nm, or no less than 300 nm, or no less than 400 nm, or no less than 500 nm.
  • the first material has a peak absorbance wavelength no greater than 700 nm, or no greater than 600 nm, or no greater than 500 nm, or no greater than 400 nm, or no greater than 300 nm.
  • the EMR has a wavelength no less than 200 nm, or no less than 250 nm, or no less than 300 nm, or no less than 400 nm, or no less than 500 nm.
  • the second material comprises carbon, nickel oxide, nickel, silver, copper, CGO, NiO-YSZ, LSCF, LSM, ferritic steels, or combinations thereof.
  • the ferritic steel is Crofer 22 APU.
  • the second material is carbon and is in the form of graphite, graphene, carbon nanoparticles, nano diamonds, or combinations thereof. Most preferably, the carbon is in the form of graphite particles.
  • the depositing is accomplished by material jetting, binder jetting, inkjet printing, aerosol jetting, or aerosol jet printing, vat photopolymerization, powder bed fusion, material extrusion, directed energy deposition, sheet lamination, ultrasonic inkjet printing, or combinations thereof.
  • the depositing is manipulated by controlling the distance from the EMR to the substrate, the EMR energy density, the EMR spectrum, the EMR voltage, the EMR exposure duration, the EMR exposure area, the EMR exposure volume, the EMR burst frequency, the EMR exposure repetition number, and combinations thereof.
  • the object does not change location between depositing and heating.
  • the EMR has a power output of no less than 1 W, or 10 W, or 100 W, or 1000 W.
  • a system comprising at least one deposition nozzle, an electromagnetic radiation (EMR) source, and a deposition receiver, wherein the deposition receiver is configured to receive EMR exposure and deposition at the same location.
  • the receiver is configured such that it receives deposition for a first time period, moves to a different location in the system to receive EMR exposure for a second time period.
  • SOFCs solid oxide fuel cells
  • a fuel cell is an electrochemical apparatus that converts the chemical energy from a fuel into electricity through an electrochemical reaction.
  • fuel cells e.g., proton-exchange membrane fuel cells (PEMFCs), solid oxide fuel cells (SOFCs).
  • PEMFCs proton-exchange membrane fuel cells
  • SOFCs solid oxide fuel cells
  • a fuel cell typically comprises an anode, a cathode, an electrolyte, an interconnect, optionally a barrier layer and/or optionally a catalyst. Both the anode and the cathode are electrodes.
  • Figures 1-5 illustrate various embodiments of the components in a fuel cell or a fuel cell stack.
  • the anode, cathode, electrolyte, and interconnect are cuboids or rectangular prisms.
  • 201 schematically represents the anode
  • 202 represents the cathode
  • 203 represents the electrolyte
  • 204 represents the barrier layers.
  • 301 schematically represents the anode
  • 302 represents the cathode
  • 303 represents the electrolyte
  • 304 represents the barrier layers
  • 305 represents the catalyst.
  • 501 schematically represents the anode
  • 502 represents the cathode
  • 503 represents the electrolyte
  • 504 represents the barrier layers
  • 505 represents the catalyst
  • 506 represents the interconnect.
  • Two fuel cell repeat units or two fuel cells form a stack as illustrated in Figure 5. As is seen, on one side, the interconnect is in contact with the largest surface of the cathode of the top fuel cell (or fuel cell repeat unit) and on the opposite side the interconnect is in contact with the largest surface of the catalyst (optional) or the anode of the bottom fuel cell (or fuel cell repeat unit).
  • These repeat units or fuel cells are connected in parallel by being stacked atop one another and sharing an interconnect in between via direct contact with the interconnect rather than via electrical wiring. This kind of configuration is in contrast to segmented-in-series (SIS) type fuel cells.
  • SIS segmented-in-series
  • the listings of material for the electrodes, the electrolyte, and the interconnect in a fuel cell are exemplary and not limiting.
  • the designations of anode material and cathode material are also not limiting because the function of the material during operation (e.g., whether it is oxidizing or reducing) determines whether the material is used as an anode or a cathode.
  • the cathode comprises perovskites, such as LSC, LSCF, LSM.
  • the cathode comprises lanthanum, cobalt, strontium, manganite.
  • the cathode is porous.
  • the cathode comprises YSZ, Nitrogen, Nitrogen Boron doped Graphene, LaO.6SrO.4CoO.2FeO.803, SrCoO.5ScO.503,
  • the cathode comprises LSCo, LCo, LSF, LSCoF. In an embodiment, the cathode comprises perovskites LaCo03, LaFe03, LaMn03, (La,Sr)Mn03, LSM-GDC, LSCF-GDC, LSC-GDC. Cathodes containing LSCF are suitable for intermediate-temperature fuel cell operation.
  • the cathode comprises a material selected from the group consisting of lanthanum strontium manganite, lanthanum strontium ferrite, and lanthanum strontium cobalt ferrite. In an embodiment, the cathode comprises lanthanum strontium manganite.
  • the anode comprises Copper, Nickle-Oxide, Nickle-Oxide-YSZ, NiO- GDC, NiO-SDC, Aluminum doped Zinc Oxide, Molybdenum Oxide, Lanthanum, strontium, chromite, ceria, perovskites (such as, LSCF [La ⁇ l-x ⁇ Sr ⁇ x ⁇ Co ⁇ l-y ⁇ Fe ⁇ y ⁇ 03] or LSM [La ⁇ l- x ⁇ Sr ⁇ x ⁇ Mn03], where x is usually 0.15-0.2 and y is 0.7 to 0.8).
  • the anode comprises SDC or BZCYYb coating or barrier layer to reduce coking and sulfur poisoning.
  • the anode is porous.
  • the anode comprises combination of electrolyte material and electrochemically active material, combination of electrolyte material and electrically conductive material.
  • the anode comprises nickel and yttria stabilized zirconia. In an embodiment, the anode is formed by reduction of a material comprising nickel oxide and yttria stabilized zirconia. In an embodiment, the anode comprises nickel and gadolinium stabilized ceria. In an embodiment, the anode is formed by reduction of a material comprising nickel oxide and gadolinium stabilized ceria.
  • the electrolyte in a fuel cell comprises stabilized zirconia e.g., YSZ, YSZ-8, Y0.16Zr0.8402.
  • the electrolyte comprises doped LaGa03, e.g., LSGM, La0.9Sr0.1Ga0.8Mg0.203.
  • the electrolyte comprises doped ceria, e.g., GDC, Gd0.2Ce0.8O2.
  • the electrolyte comprises stabilized bismuth oxide e.g., BVCO, Bi2V0.9Cu0.105.35.
  • the electrolyte comprises zirconium oxide, yttria stabilized zirconium oxide (also known as YSZ, YSZ8 (8mole% YSZ)), ceria, gadolinia, scandia, magnesia, calcia.
  • yttria stabilized zirconium oxide also known as YSZ, YSZ8 (8mole% YSZ)
  • ceria gadolinia
  • scandia magnesia
  • calcia calcia
  • the electrolyte is sufficiently impermeable to prevent significant gas transport and prevent significant electrical conduction; and allow ion conductivity.
  • the electrolyte comprises doped oxide such as cerium oxide, yttrium oxide, bismuth oxide, lead oxide, lanthanum oxide.
  • the electrolyte comprises perovskite, such as, LaCoFe03 or LaCo03 or CeO.9GdO.102 (GDC) or CeO.9SmO.102 (SDC, samaria doped ceria) or scandia stabilized zirconia.
  • the electrolyte comprises a material selected from the group consisting of zirconia, ceria, and gallia.
  • the material is stabilized with a stabilizing material selected from the group consisting of scandium, samarium, gadolinium, and yttrium.
  • the material comprises yttria stabilized zirconia.
  • the interconnect comprises silver, gold, platinum, AISI441, ferritic stainless steel, stainless steel, Lanthanum, Chromium, Chromium Oxide, Chromite, Cobalt, Cesium, Cr203.
  • the anode comprises LaCr03 coating on Cr203 or NiCo204 or MnCo204 coatings.
  • the interconnect surface is coated with Cobalt and/or Cesium.
  • the interconnect comprises ceramics.
  • the interconnect comprises Lanthanum Chromite or doped Lanthanum Chromite.
  • the interconnect is made of a material comprising metal, stainless steel, ferritic steel, crofer, lanthanum chromite, silver, metal alloys, nickel, nickel oxide, ceramics, or graphene.
  • the fuel cell comprises a catalyst, such as, platinum, palladium, scandia, chromium, cobalt, cesium, Ce02, nickle, nickle oxide, zine, copper, titantia, ruthenium, rhodiu, MoS2, molybdenum, rhenium, vandia, manganese, magnesium, iron.
  • the catalyst promotes methane reforming reactions to generate hydrogen and carbon monoxide for them to be oxidized in the fuel cell.
  • the catalyst is part of the anode, especially nickel anode has inherent methane reforming properties.
  • the catalyst is between l%-5%, or 0.1% to 10% by mass.
  • the catalyst is used on the anode surface or in the anode. In various embodiments, such anode catalysts reduce harmful coking reactions and carbon deposits. In various embodiments, simple oxide version of catalysts is used or perovskite. For example, 2% mass Ce02 catalyst is used for methane-powered fuel cells. In various embodiments, the catalyst is dipped or coated on the anode. In various embodiments, the catalyst is made by an additive manufacturing machine (AMM) and incorporated into the fuel cell using the AMM.
  • AMM additive manufacturing machine
  • the unique manufacturing methods as discussed herein have allowed the making of ultra-thin fuel cells and fuel cell stacks.
  • the fuel cell has at least one thick layer per repeat unit, like the anode (an anode-supported fuel cell) or the interconnect (an interconnect-supported fuel cell).
  • the pressing or compression step is typically necessary to assemble the fuel cell components to achieve gas tightness and/or proper electrical contact in traditional manufacturing processes.
  • the thick layers are necessary not only because traditional methods (like tape casting) cannot produce ultra-thin layers but also because the layers have to be thick to endure the pressing or compression step.
  • the preferred manufacturing methods of this disclosure have eliminated the need for pressing or compression.
  • the preferred manufacturing methods of this disclosure have also enabled the making of ultra-thin layers.
  • the multiplicity of the layers in a fuel cell or a fuel cell stack provides sufficient structural integrity for proper operation when they are made according to this disclosure.
  • a fuel cell comprising an anode no greater than 1 mm or 500 microns or 300 microns or 100 microns or 50 microns or no greater than 25 microns in thickness, a cathode no greater than 1 mm or 500 microns or 300 microns or 100 microns or 50 microns or no greater than 25 microns in thickness, and an electrolyte no greater than 1 mm or 500 microns or 300 microns or 100 microns or 50 microns or 30 microns in thickness.
  • the fuel cell comprises an interconnect having a thickness of no less than 50 microns.
  • a fuel cell comprises an anode no greater than 25 microns in thickness, a cathode no greater than 25 microns in thickness, and an electrolyte no greater than 10 microns or 5 microns in thickness.
  • the fuel cell comprises an interconnect having a thickness of no less than 50 microns.
  • the interconnect has a thickness of from 50 microns to 5 cm.
  • the fuel cell comprises an anode no greater than 100 microns in thickness, a cathode no greater than 100 microns in thickness, an electrolyte no greater than 20 microns in thickness, and an interconnect no greater than 30 microns in thickness.
  • a fuel cell comprises an anode no greater than 50 microns in thickness, a cathode no greater than 50 microns in thickness, an electrolyte no greater than 10 microns in thickness, and an interconnect no greater than 25 microns in thickness.
  • the interconnect has a thickness in the range of from 1 micron to 20 microns.
  • the fuel cell comprises a barrier layer between the anode and the electrolyte, or a barrier layer between the cathode and the electrolyte, or both barrier layers.
  • the barrier layers are the interconnects. In such cases, the reactants are directly injected into the anode and the cathode.
  • the cathode has a thickness of no greater than 15 microns, or no greater than 10 microns, or no greater than 5 microns.
  • the anode has a thickness of no greater than 15 microns, or no greater than 10 microns, or no greater than 5 microns.
  • the electrolyte has a thickness of no greater than 5 microns, or no greater than 2 microns, or no greater than 1 micron, or no greater than 0.5 micron.
  • the interconnect is made of a material comprising metal, stainless steel, silver, metal alloys, nickel, nickel oxide, ceramics, or graphene.
  • the fuel cell has a total thickness of no less than 1 micron.
  • each fuel cell comprises an anode no greater than 25 microns in thickness, a cathode no greater than 25 microns in thickness, an electrolyte no greater than 10 microns in thickness, and an interconnect having a thickness of from 100 nm to 100 microns.
  • each fuel cell comprises a barrier layer between the anode and the electrolyte, or a barrier layer between the cathode and the electrolyte, or both barrier layers.
  • the barrier layers are the interconnects.
  • the interconnect is made of silver.
  • the interconnect has a thickness of from 500 nm to 1000 nm.
  • the interconnect is made of a material comprising metal, stainless steel, silver, metal alloys, nickel, nickel oxide, ceramics, or graphene.
  • the cathode has a thickness of no greater than 15 microns, or no greater than 10 microns, or no greater than 5 microns.
  • the anode has a thickness of no greater than 15 microns, or no greater than 10 microns, or no greater than 5 microns.
  • the electrolyte has a thickness of no greater than 5 microns, or no greater than 2 microns, or no greater than 1 micron, or no greater than 0.5 micron.
  • each fuel cell has a total thickness of no less than 1 micron.
  • steps (a)-(c) are performed using additive manufacturing.
  • said additive manufacturing uses extrusion, photopolymerization, powder bed fusion, material jetting, binder jetting, directed energy deposition, or lamination.
  • the method comprises assembling the anode, the cathode, and the electrolyte using additive manufacturing. In an embodiment, the method comprises forming an interconnect and assembling the interconnect with the anode, the cathode, and the electrolyte.
  • the method comprises making at least one barrier layer.
  • said at least one barrier layer is used between the electrolyte and the cathode or between the electrolyte and the anode or both.
  • said at least one barrier layer is also an interconnect.
  • the method comprises heating the fuel cell such that shrinkage rates of the anode, the cathode, and the electrolyte are matched. In an embodiment, such heating takes place for no greater than 30 minutes, preferably no greater than 30 seconds, and most preferably no greater than 30 milliseconds. In this disclosure, matching shrinkage rates during heating is discussed in detail below (matching SRTs).
  • a fuel cell comprises a first composition and a second composition, wherein the first composition has a first shrinkage rate and the second composition has a second shrinkage rate
  • the heating described in this disclosure preferably takes place such that the difference between the first shrinkage rate and the second shrinkage rate is no greater than 75% of the first shrinkage rate.
  • the heating makes use of electromagnetic radiation (EMR).
  • EMR electromagnetic radiation
  • EMR comprises UV light, near ultraviolet light, near infrared light, infrared light, visible light, laser, electron beam.
  • heating is performed in situ, namely in the same machine and in the same location in that machine as the layers are deposited.
  • Also disclosed herein is a method of making a fuel cell stack comprising a multiplicity of fuel cells, the method comprising (a) forming an anode no greater than 25 microns in thickness in each fuel cell, (b) forming a cathode no greater than 25 microns in thickness in each fuel cell, (c) forming an electrolyte no greater than 10 microns in thickness in each fuel cell, and (d) producing an interconnect having a thickness of from 100 nm to 100 microns in each fuel cell.
  • steps (a)-(d) are performed using additive manufacturing.
  • said additive manufacturing uses extrusion, photopolymerization, powder bed fusion, material jetting, binder jetting, directed energy deposition, and/or lamination.
  • the method comprises assembling the anode, the cathode, the electrolyte, and the interconnect using additive manufacturing. In an embodiment, the method comprises making at least one barrier layer in each fuel cell. In an embodiment, said at least one barrier layer is used between the electrolyte and the cathode or between the electrolyte and the anode or both. In an embodiment, said at least one barrier layer is the interconnect.
  • the method comprises heating each fuel cell such that shrinkage rates of the anode, the cathode, and the electrolyte are matched. In an embodiment, such heating takes place for no greater than 30 minutes, or no greater than 30 seconds, or no greater than 30 milliseconds.
  • said heating comprises electromagnetic radiation (EMR).
  • EMR electromagnetic radiation
  • EMR comprises UV light, near ultraviolet light, near infrared light, infrared light, visible light, laser, electron beam. In an embodiment, heating is performed in situ.
  • the method comprises heating the entire fuel cell stack such that shrinkage rates of the anode, the cathode, and the electrolyte are matched. In an embodiment, such heating takes place for no greater than 30 minutes, or no greater than 30 seconds, or no greater than 30 milliseconds.
  • an electrolyte comprising (a) formulating a colloidal suspension, wherein the colloidal suspension comprises an additive, particles having a range of diameters and a size distribution, and a solvent; (b) forming an electrolyte comprising the colloidal suspension; and (c) heating at least a portion of the electrolyte; wherein formulating the colloidal suspension is preferably optimized by controlling the pH of the colloidal suspension, or concentration of the binder in the colloidal suspension, or composition of the binder in the colloidal suspension, or the range of diameters of the particles, or maximum diameter of the particles, or median diameter of the particles, or the size distribution of the particles, or boiling point of the solvent, or surface tension of the solvent, or composition of the solvent, or thickness of the minimum dimension of the electrolyte, or the composition of the particles, or combinations thereof.
  • a method of making a fuel cell comprising (a) obtaining a cathode and an anode; (b) modifying the cathode surface and the anode surface; (c) formulating a colloidal suspension, wherein the colloidal suspension comprises an additive, particles having a range of diameters and a size distribution, and a solvent; (d) forming an electrolyte comprising the colloidal suspension between the modified anode surface and the modified cathode surface; and (e) heating at least a portion of the electrolyte; wherein formulating the colloidal suspension comprises controlling pH of the colloidal suspension, or concentration of the binder in the colloidal suspension, or composition of the binder in the colloidal suspension, or the range of diameters of the particles, or maximum diameter of the particles, or median diameter of the particles, or the size distribution of the particles, or boiling point of the solvent, or surface tension of the solvent, or composition of the solvent, or thickness of the minimum dimension of the electrolyte, or the composition of the particles,
  • the anode and the cathode are obtained via any suitable means.
  • the modified anode surface and the modified cathode surface have a maximum height profile roughness that is less than the average diameter of the particles in the colloidal suspension.
  • the maximum height profile roughness refers to the maximum distance between any trough and an adjacent peak as illustrated in Figure 9.
  • the anode surface and the cathode surface are modified via any suitable means.
  • a method of making a fuel cell comprising (a) obtaining a cathode and an anode; (b) formulating a colloidal suspension, wherein the colloidal suspension comprises an additive, particles having a range of diameters and a size distribution, and a solvent; (c) forming an electrolyte comprising the colloidal suspension between the anode and the cathode; and (d) heating at least a portion of the electrolyte; wherein formulating the colloidal suspension comprises controlling pH of the colloidal suspension, or concentration of the binder in the colloidal suspension, or composition of the binder in the colloidal suspension, or the range of diameters of the particles, or maximum diameter of the particles, or median diameter of the particles, or the size distribution of the particles, or boiling point of the solvent, or surface tension of the solvent, or composition of the solvent, or thickness of the minimum dimension of the electrolyte, or the composition of the particles, or combinations thereof.
  • the anode and the cathode are obtained via any suitable means.
  • the anode surface in contact with the electrolyte and the cathode surface in contact with the electrolyte have a maximum height profile roughness that is less than the average diameter of the particles in the colloidal suspension.
  • the solvent comprises water.
  • the solvent comprises an organic component.
  • the solvent comprises ethanol, butanol, alcohol, terpineol, Diethyl ether 1,2-Dimethoxyethane (DME (ethylene glycol dimethyl ether), 1- Propanol (n-propanol, n-propyl alcohol), or butyl alcohol.
  • DME Diethyl ether 1,2-Dimethoxyethane
  • the solvent surface tension is less than half of water's surface tension in air. In an embodiment, the solvent surface tension is less than 30 mN/m at atmospheric conditions.
  • the electrolyte is formed adjacent to a first substrate. In an embodiment, the electrolyte is formed between a first substrate and a second substrate. In an embodiment, the first substrate has a maximum height profile roughness that is less than the average diameter of the particles. In an embodiment, the particles have a packing density greater than 40%, or greater than 50%, or greater than 60%. In an embodiment, the particles have a packing density close to the random close packing (RCP) density.
  • RCP random close packing
  • Random close packing is an empirical parameter used to characterize the maximum volume fraction of solid objects obtained when they are packed randomly.
  • a container is randomly filled with objects, and then the container is shaken or tapped until the objects do not compact any further, at this point the packing state is RCP.
  • the packing fraction is the volume taken by number of particles in a given space of volume.
  • the packing fraction determines the packing density. For example, when a solid container is filled with grain, shaking the container will reduce the volume taken up by the objects, thus allowing more grain to be added to the container. Shaking increases the density of packed objects. When shaking no longer increases the packing density, a limit is reached and if this limit is reached without obvious packing into a regular crystal lattice, this is the empirical random close-packed density.
  • the median particle diameter is preferably between 50 nm and 1000 nm, or between 100 nm and 500 nm, or approximately 200 nm.
  • the first substrate comprises particles having a median particle diameter, wherein the median particle diameter of the electrolyte is no greater than 10 times and no less than 1/10 of the median particle diameter of the first substrate.
  • the first substrate comprises a particle size distribution that is bimodal, i.e. having a first mode and a second mode, each having a median particle diameter.
  • the median particle diameter in the first mode of the first substrate is greater than 2 times, or greater than 5 times, or greater than 10 times that of the second mode.
  • the particle size distribution of the first substrate is adjusted to change the behavior of the first substrate during heating.
  • the first substrate has a shrinkage that is a function of heating temperature.
  • the particles in the colloidal suspension has a maximum particle diameter and a minimum particle diameter, wherein the maximum particle diameter is less than 2 times, or less than 3 times, or less than 5 times, or less than 10 times the minimum particle diameter.
  • the minimum dimension of the electrolyte is less than 10 microns, or less than 2 microns, or less than 1 micron, or less than 500 nm.
  • the electrolyte has a gas permeability of no greater than 1 millidarcy, preferably no greater than 100 microdarcy, and most preferably no greater than 1 microdarcy. Preferably, the electrolyte has no cracks penetrating through the minimum dimension of the electrolyte.
  • the boiling point of the solvent is no less than 200 °C, or no less than 100 °C, or no less than 75°C. In an embodiment, the boiling point of the solvent is no greater than 125 °C, or no greater than 100 °C, or no greater than 85 °C, no greater than 70 °C.
  • the pH of the colloidal suspension is no less than 7, or no less than 9, or no less than 10.
  • the additive comprises polyethylene glycol (PEG), ethyl cellulose, polyvinylpyrrolidone (PVP), polyvinyl butyral (PVB), butyl benzyl phthalate (BBP), polyalkalyne glycol (PAG).
  • PEG polyethylene glycol
  • PVP polyvinylpyrrolidone
  • PVB polyvinyl butyral
  • BBP butyl benzyl phthalate
  • PAG polyalkalyne glycol
  • the additive concentration is no greater than 100 mg/cm3, or no greater than 50 mg/cm3, or no greater than 30 mg/cm3, or no greater than 25 mg/cm3.
  • the colloidal suspension is milled. In an embodiment, the colloidal suspension is milled using a rotational mill. In an embodiment, the rotational mill is operated at no less than 20 rpm, or no less than 50 rpm, or no less than 100 rpm, or no less than 150 rpm.
  • the colloidal suspension is milled using zirconia milling balls or tungsten carbide balls. In an embodiment, the colloidal suspension is milled for no less than 2 hours, or no less than 4 hours, or no less than 1 day, or no less than 10 days.
  • the particle concentration in the colloidal suspension is no greater than 30 wt%, or no greater than 20 wt%, or no greater than 10 wt%. In an embodiment, the particle concentration in the colloidal suspension is no less than 2 wt%. In an embodiment, the particle concentration in the colloidal suspension is no greater than 10 vol%, or no greater than 5 vol%, or no greater than 3 vol%, or no greater than 1 vol%. In an embodiment, the particle concentration in the colloidal suspension is no less than 0.1 vol%.
  • the electrolyte is formed using an additive manufacturing machine (AMM).
  • the first substrate is formed using an AMM.
  • said heating comprises the use of electromagnetic radiation (EMR).
  • EMR electromagnetic radiation
  • the EMR comprises UV light, near ultraviolet light, near infrared light, infrared light, visible light, laser.
  • the first substrate and the electrolyte are heated to cause co sintering.
  • the first substrate, the second substrate, and the electrolyte are heated to cause co-sintering.
  • the EMR is controlled to preferentially sinter the first substrate over the electrolyte.
  • the electrolyte is in compression throughout its thickness after heating.
  • the first substrate and the second substrate apply compressive stress to the electrolyte after heating.
  • the first substrate and the second substrate are anode and cathode of a fuel cell.
  • the minimum dimension of the electrolyte is between 500 nm and 5 microns. In an embodiment, the minimum dimension of the electrolyte is between 1 micron and 2 microns.
  • SOFCs solid oxide fuel cells
  • the fuel cell stack is configured to be made into a cartridge form, such as an easily detachable flanged fuel cell cartridge (FCC) design.
  • FCC easily detachable flanged fuel cell cartridge
  • Figure 11C illustrates the top view and bottom view of an embodiment of a FCC, in which the length of the oxidant side of the FCC is shown L 0 , the length of the fuel side of the FCC is shown L f , the width of the oxidant (air) entrance is shown W 0 , the width of the fuel entrance is shown W f .
  • two fluid exits are shown (Air Outlet 1132 and Fuel Outlet 1134). In some cases, the anode exhaust and the cathode exhaust are mixed and extracted through one fluid exit.
  • Figure 11B illustrates cross-sectional views of the FCC, wherein air flow is sealed from the anode and fuel flow is sealed from the cathode. The bolts are isolated electrically with a seal as well.
  • the seal is a dual functional seal (DFS) comprising YSZ (yttria-stabilized zirconia) or a mixture of 3YSZ (3 mol% Y2O3 in Zr0 2 ) and 8YSZ (8 mol% Y2O3 in Zr0 2 ).
  • the DFS is impermeable to non-ionic substances and electrically insulating.
  • the mass ratio of 3YSZ/8YSZ is in the range of from 10/90 to 90/10.
  • the mass ratio of 3YSZ/8YSZ is about 50/50.
  • the mass ratio of 3YSZ/8YSZ is 100/0 or 0/100.
  • a fuel cell cartridge comprising an anode, a cathode, an electrolyte, an interconnect, a fuel entrance on a fuel side of the FCC, an oxidant entrance on an oxidant side of the FCC, at least one fluid exit, wherein the fuel entrance has a width of W f , the fuel side of the FCC has a length of L f , the oxidant entrance has a width of W 0 , the oxidant side of the FCC has a length of L 0 , wherein W f /L f is in the range of 0.1 to 1.0, or 0.1 to 0.9, or 0.2 to 0.9, or 0.5 to 0.9, or 0.5 to 1.0 and W 0 /L 0 is in the range of 0.1 to 1.0, or 0.1 to 0.9, or 0.2 to 0.9, or 0.5 to 0.9, or 0.5 to 1.0.
  • W 0 /L 0 is in the range of 0.1 to 1.0, or 0.1 to 0.9
  • said entrances and exit are on one surface of the FCC and said FCC comprises no protruding fluid passage on said surface.
  • said surface is smooth with a maximum elevation change of no greater than 1 mm, or no greater than 100 microns, or no greater than 10 microns.
  • the FCC comprises a barrier layer between the electrolyte and the cathode or between the electrolyte and the anode or both.
  • the FCC comprises dual functional seal that is impermeable to non-ionic substances and electrically insulating.
  • said dual functional seal comprises YSZ (yttria-stabilized zirconia) or a mixture of 3YSZ (3 mol% Y2O3 in Zr0 2 ) and 8YSZ (8 mol% Y2O3 in ZrCh).
  • said interconnect comprises no fluid dispersing element and said anode and cathode comprise fluid dispersing components.
  • said anode and cathode comprise fluid dispersing components.
  • interconnect comprises no fluid dispersing element and said anode and cathode comprise fluid channels.
  • the FCC is detachably fixed to a mating surface and not soldered nor welded to said mating surface.
  • the FCC is bolted to or pressed to said mating surface.
  • said mating surface comprises matching fuel entrance, matching oxidant entrance, and at least one matching fluid exit.
  • a fuel cell cartridge comprising an anode, a cathode, an electrolyte, an interconnect, a fuel entrance, an oxidant entrance, at least one fluid exit, wherein said entrances and exit are on one surface of the FCC and said FCC comprises no protruding fluid passage on said surface.
  • said surface is smooth with a maximum elevation change of no greater than 1 mm, or no greater than 100 microns, or no greater than 10 microns.
  • the FCC comprises dual functional seal that is impermeable to non ionic substances and electrically insulating.
  • said interconnect comprises no fluid dispersing element and said anode and cathode comprise fluid dispersing components.
  • said interconnect comprises no fluid dispersing element and said anode and cathode comprise fluid channels.
  • the FCC is detachably fixed to a mating surface and not soldered nor welded to said mating surface.
  • the FCC is bolted to or pressed to said mating surface.
  • said mating surface comprises matching fuel entrance, matching oxidant entrance, and at least one matching fluid exit.
  • FCC fuel cell cartridge
  • the FCC comprises an anode, a cathode, an electrolyte, an
  • a fuel entrance on a fuel side of the FCC an oxidant entrance on an oxidant side of the FCC, at least one fluid exit
  • the fuel entrance has a width of W f
  • the fuel side of the FCC has a length of L f
  • the oxidant entrance has a width of W 0
  • the oxidant side of the FCC has a length of L 0
  • W f /L f is in the range of 0.1 to 1.0, or 0.1 to 0.9, or 0.2 to 0.9, or 0.5 to 0.9, or 0.5 to 1.0
  • W 0 /L 0 is in the range of 0.1 to 1.0, or 0.1 to 0.9, or 0.2 to 0.9, or 0.5 to 0.9, or 0.5 to 1.0
  • the FCC is detachably fixed to the mating surface.
  • the FCC is not soldered nor welded to said mating surface.
  • the FCC is bolted to or pressed to said mating surface.
  • said mating surface comprises matching fuel entrance, matching oxidant entrance, and at least one matching fluid exit.
  • said entrances and exit are on one surface of the FCC and said FCC comprises no protruding fluid passage on said surface.
  • said surface is smooth with a maximum elevation change of no greater than 1 mm, or no greater than 100 microns, or no greater than 10 microns.
  • said interconnect comprises no fluid dispersing element and said anode and cathode comprise fluid dispersing components, such as fluid channels.
  • a method comprising pressing or bolting together a fuel cell cartridge (FCC) and a mating surface, said method excluding welding or soldering together the FCC and the mating surface, wherein the FCC comprises an anode, a cathode, an electrolyte, an interconnect, a fuel entrance on a fuel side of the FCC, an oxidant entrance on an oxidant side of the FCC, at least one fluid exit, wherein the fuel entrance has a width of W f , the fuel side of the FCC has a length of L f , the oxidant entrance has a width of W 0 , the oxidant side of the FCC has a length of L 0 , wherein W f /L f is in the range of 0.1 to 1.0, or 0.1 to 0.9, or 0.2 to 0.9, or 0.5 to 0.9, or 0.5 to 1.0 and W 0 /L 0 is in the range of 0.1 to 1.0, or 0.1
  • said entrances and exit are on one surface of the FCC and said FCC comprises no protruding fluid passage on said surface.
  • said surface is smooth with a maximum elevation change of no greater than 1 mm, or no greater than 100 microns, or no greater than 10 microns.
  • said interconnect comprises no fluid dispersing element and said anode and cathode comprise fluid dispersing components.
  • said interconnect comprises no fluid dispersing element and said anode and cathode comprise fluid channels.
  • a fuel cell cartridge comprising a fuel cell and a fuel cell casing, wherein the fuel cell comprises an anode, a cathode, and an electrolyte, wherein at least a portion of the fuel cell casing is made of the same material as the electrolyte.
  • the electrolyte is in contact with the portion of the fuel cell casing made of the same material.
  • the electrolyte and the portion of the fuel cell casing are made of a dual functional seal (DFS), wherein the DFS comprises 3YSZ (3 mol% Y203 in Zr02) and 8YSZ (8 mol% Y203 in Zr02), wherein the mass ratio of 3YSZ/8YSZ is in the range of from 100/0 to 0/100 or from 10/90 to 90/10 and wherein the DFS is impermeable to non-ionic substances and electrically insulating.
  • the mass ratio of 3YSZ/8YSZ is about 50/50 or 40/60 or 60/40 or 30/70 or 70/30 or 20/80 or 80/20.
  • said fuel cell casing comprises a fuel entrance and fuel passage for the anode, an oxidant entrance and oxidant passage for the cathode, and at least one fluid exit.
  • said entrances and exit are on one surface of the FCC and said FCC comprises no protruding fluid passage on said surface.
  • the fuel cell casing is in contact with at least a portion of the anode.
  • the FCC comprises a barrier layer between the electrolyte and the cathode and between the fuel cell casing and the cathode.
  • the FCC comprises an interconnect, wherein the interconnect comprises no fluid dispersing element and said anode and cathode comprise fluid dispersing components.
  • the FCC comprises an interconnect, wherein the interconnect comprises no fluid dispersing element and said anode and cathode comprise fluid channels.
  • the FCC is detachably fixed to a mating surface and not soldered nor welded to said mating surface.
  • said mating surface comprises matching fuel entrance, matching oxidant entrance, and at least one matching fluid exit.
  • a dual functional seal comprising 3YSZ (3 mol% Y203 in Zr02) and 8YSZ (8 mol% Y203 in Zr02), wherein the mass ratio of 3YSZ/8YSZ is in the range of from 10/90 to 90/10 and wherein the DFS is impermeable to non-ionic substances and electrically insulating.
  • the mass ratio of 3YSZ/8YSZ is about 50/50 or 40/60 or 60/40 or 30/70 or 70/30 or 20/80 or 80/20.
  • the DFS is used as an electrolyte in a fuel cell or as a portion of a fuel cell casing or both.
  • a method comprising providing a dual functional seal (DFS) in a fuel cell system, wherein the DFS comprises 3YSZ (3 mol% Y203 in Zr0 2 ) and 8YSZ (8 mol% Y2O3 in Zr0 2 ), wherein the mass ratio of 3YSZ/8YSZ is in the range of from 100/0 to 0/100 or from 10/90 to 90/10 and wherein the DFS is impermeable to non-ionic substances and electrically insulating.
  • the mass ratio of 3YSZ/8YSZ is about 50/50 or 40/60 or 60/40 or 30/70 or 70/30 or 20/80 or 80/20.
  • the DFS is used as electrolyte or a portion of a fuel cell casing or both in the fuel cell system.
  • said portion of a fuel cell casing is the entire fuel cell casing.
  • said portion of a fuel cell casing is a coating on the fuel cell casing.
  • the electrolyte and said portion of a fuel cell casing are in contact.
  • a fuel cell system comprising an anode having six surfaces, a cathode having six surfaces, an electrolyte, and an anode surround in contact with at least three surfaces of the anode, wherein the electrolyte is part of the anode surround and said anode surround is made of the same material as the electrolyte.
  • said same material is a dual functional seal (DFS) comprising 3YSZ (3 mol% Y203 in Zr02) and 8YSZ
  • the mass ratio of 3YSZ/8YSZ is in the range of from 100/0 to 0/100 or from 10/90 to 90/10 and wherein the DFS is impermeable to non-ionic substances and electrically insulating.
  • the mass ratio of 3YSZ/8YSZ is about 50/50 or 40/60 or 60/40 or 30/70 or 70/30 or 20/80 or 80/20.
  • the anode surround is in contact with five surfaces of the anode.
  • the fuel cell system comprises a barrier layer between the cathode and a cathode surround, wherein the barrier layer is in contact with at least three surfaces of the cathode, wherein the electrolyte is part of the cathode surround and said cathode surround is made of the same material as the electrolyte.
  • the fuel cell system comprises fuel passage and oxidant passage in the anode surround and the cathode surround.
  • the fuel cell system comprises an interconnect, wherein the interconnect comprises no fluid dispersing element and said anode and cathode comprise fluid dispersing components.
  • the fuel cell system comprises an interconnect, wherein the interconnect comprises no fluid dispersing element and said anode and cathode comprise fluid channels.
  • SRT refers to a component of the strain rate tensor.
  • Matching SRTs is contemplated in both heating and cooling processes. In a fuel cell, multiple materials or compositions exist. These different materials or compositions often have different thermal expansion coefficients. As such, the heating or cooling process often causes strain or even cracks in the material.
  • a treating process heating or cooling to match the SRTs of different materials/compositions to reduce, minimize, or even eliminate undesirable effects.
  • FIG. 7 shows the SRTs of a first composition and a second composition as a function of temperature.
  • the SRTs are measured in mm/min.
  • the difference between the first SRT and the second SRT is no greater than 50% or 30% or 20% of the first SRT.
  • heating is achieved via at least one of the following:
  • heating comprises electromagnetic radiation (EMR).
  • EMR electromagnetic radiation
  • EMR comprises UV light, near ultraviolet light, near infrared light, infrared light, visible light, laser, electron beam.
  • the first composition and the second composition are heated at the same time. In an embodiment, the first composition and the second composition are heated at different times. In an embodiment, the first composition is heated for a first period of time, the second composition is heated for a second period of time, wherein at least a portion of the first period of time overlaps with the second period of time.
  • heating takes places more than once for the first composition, or for the second composition, or for both.
  • the first composition and the second composition are heated at different temperatures.
  • the first composition and the second composition are heated using different means.
  • the first composition and the second composition are heated for different periods of time.
  • heating the first composition causes at least partial heating of the second composition, for example, via conduction.
  • heating causes densification of the first composition, or the second composition, or both.
  • the first composition is heated to achieve partial densification resulting in a modified first SRT; and then the first and second compositions are heated such that the difference between the modified first SRT and the second SRT is no greater than 75% of the first modified SRT.
  • the first composition is heated to achieve partial densification resulting in a modified first SRT
  • the second composition is heated to achieve partial densification resulting in a modified second SRT; and then the first and second compositions are heated such that the difference between the modified first SRT and the second modified SRT is no greater than 75% of the first modified SRT.
  • the fuel cell comprises a third composition having a third SRT.
  • the third composition is heated such that the difference between the first SRT and the third SRT is no greater than 75% of the first SRT.
  • the third composition is heated to achieve partial densification resulting in a modified third SRT; and then the first and second and third compositions are heated such that the difference between the first SRT and the modified third SRT is no greater than 75% of the first SRT.
  • the first and second and third compositions are heated to achieve partial densification resulting in a modified first SRT, a modified second SRT, and a modified third SRT; and then the first and second and third compositions are heated such that the difference between the modified first SRT and the modified second SRT is no greater than 75% of the modified first SRT and the difference between the modified first SRT and the modified third SRT is no greater than 75% of the modified first SRT.
  • the method produces a crack free electrolyte in the fuel cell.
  • heating is performed in situ. In various embodiments, heating causes sintering or co-sintering or both. In various embodiments, heating takes place for no greater than 30 minutes, or no greater than 30 seconds, or no greater than 30 milliseconds.
  • a process flow diagram is shown for forming and heating at least a portion of a fuel cell.
  • 810 represents forming composition 1.
  • 820 represents heating composition 1 at temperature T1 for time tl.
  • 830 represents forming composition 2.
  • 840 represents heating composition 1 and composition 2 simultaneously at temperature T2 for time t2, wherein at T2, the difference between SRT of composition 1 and SRT of composition 2 is no greater than 75% of SRT of composition 1.
  • 840 represents heating composition 1 and composition 2 simultaneously at temperature T2 and T2' (for example, using different heating mechanisms) for time t2, wherein at T2 and T2', the difference between SRT of composition 1 and SRT of composition 2 is no greater than 75% of SRT of composition 1.
  • Example 1 Making a fuel cell stack.
  • Example 1 is illustrative of the preferred method of making a fuel cell stack.
  • the method uses an AMM model no. 0012323 from Ceradrop and an EMR model no. 092309423 from Xenon Corp.
  • An interconnect substrate is put down to start the print.
  • an anode layer is made by the AMM.
  • This layer is deposited by the AMM as a slurry A, having the composition as shown in the table below.
  • This layer is allowed to dry by applying heat via an infrared lamp.
  • This anode layer is sintered by hitting it with an electromagnetic pulse from a xenon flash tube for 1 second.
  • An electrolyte layer is formed on top of the anode layer by the AMM depositing a slurry B, having the composition shown in the table below. This layer is allowed to dry by applying heat via an infrared lamp. This electrolyte layer is sintered by hitting it with an electromagnetic pulse from a xenon flash tube for 60 seconds.
  • a cathode layer is formed on top of the electrolyte layer by the AMM depositing a slurry C, having the composition shown in the table below. This layer is allowed to dry by applying heat via an infrared lamp. This cathode layer is sintered by hitting it with an electromagnetic pulse from a xenon flash tube for 1/2 second.
  • An interconnect layer is formed on top of the cathode layer by the AMM depositing a slurry D, having the composition shown in the table below. This layer is allowed to dry by applying heat via an infrared lamp. This interconnect layer is sintered by hitting it with an electromagnetic pulse from a xenon flash tube for 30 seconds.
  • Example 4 CGO in water.
  • an electrolyte 1001 (YSZ) is printed and sintered on an electrode 1002 (NiO-YSZ).
  • the scanning electron microscopy image shows the side view of the sintered structures, which demonstrates gas-tight contact between the electrolyte and the electrode, full densification of the electrolyte, and sintered and porous electrode microstructures.
  • Example 7 Fuel cell stack configurations.
  • a 48-Volt fuel cell stack has 69 cells with about 1000 W of power output.
  • the fuel cell in this stack has a dimension of about 4 cm x 4 cm in length and width and about 7 cm in height.
  • a 48-Volt fuel cell stack has 69 cells with about 5000 W of power output.
  • the fuel cell in this stack has dimensions of about 8.5 cm x 8.5 cm in length and width and about 7 cm in height.

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  • Chemical & Material Sciences (AREA)
  • Engineering & Computer Science (AREA)
  • Manufacturing & Machinery (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • General Chemical & Material Sciences (AREA)
  • Electrochemistry (AREA)
  • Sustainable Development (AREA)
  • Sustainable Energy (AREA)
  • Life Sciences & Earth Sciences (AREA)
  • Inorganic Chemistry (AREA)
  • Materials Engineering (AREA)
  • Fuel Cell (AREA)
  • Inert Electrodes (AREA)

Abstract

L'invention concerne un procédé de fabrication d'une pile à combustible comprenant la formation d'une anode, d'une cathode et d'un électrolyte à l'aide d'une machine de fabrication additive. L'électrolyte est placé entre l'anode et la cathode. De préférence, le flux de courant électrique est perpendiculaire à l'électrolyte dans la direction latérale lorsque la pile à combustible est en cours d'utilisation. De préférence, le procédé comprend la fabrication d'une interconnexion, d'une couche barrière et d'une couche de catalyseur à l'aide de la machine de fabrication additive.
PCT/US2019/059925 2018-11-06 2019-11-05 Procédé et système de fabrication d'une pile à combustible WO2020097120A1 (fr)

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US16/674,695 2019-11-05
US16/674,580 2019-11-05
US16/674,695 US11735755B2 (en) 2018-11-06 2019-11-05 System and method for integrated deposition and heating
US16/674,657 US11575142B2 (en) 2018-11-06 2019-11-05 Method and system for making a fuel cell
US16/674,580 US20200176803A1 (en) 2018-11-06 2019-11-05 Method of Making Fuel Cells and a Fuel Cell Stack
US16/674,629 2019-11-05
US16/674,657 2019-11-05

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JP7141431B2 (ja) 2020-09-16 2022-09-22 本田技研工業株式会社 燃料電池積層体の製造方法及び燃料電池スタックの製造方法
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