Electrolytic process to produce sodium hypochlorite using sodium ion conductive ceramic membranes

Balagopal, Shekar; Malhotra, Vinod; Pendleton, Justin; Reid, Kathy Jo

Advanced Search OptionsAdvanced Search queries use a traditional Term Search. For more info, see our FAQ.

All Fields:

Patent Title:

Abstract:

Assignee:

Inventor(s):

Patent Number:

Patent Classification (CPC):

All Classifications
A - human necessities
A01 - agriculture
A21 - baking
A22 - butchering
A23 - foods or foodstuffs
A24 - tobacco
A41 - wearing apparel
A42 - headwear
A43 - footwear
A44 - haberdashery
A45 - hand or travelling articles
A46 - brushware
A47 - furniture
A61 - medical or veterinary science
A62 - life-saving
A63 - sports
A99 - subject matter not otherwise provided for in this section
B - performing operations
B01 - physical or chemical processes or apparatus in general
B02 - crushing, pulverising, or disintegrating
B03 - separation of solid materials using liquids or using pneumatic tables or jigs
B04 - centrifugal apparatus or machines for carrying-out physical or chemical processes
B05 - spraying or atomising in general
B06 - generating or transmitting mechanical vibrations in general
B07 - separating solids from solids
B08 - cleaning
B09 - disposal of solid waste
B21 - mechanical metal-working without essentially removing material
B22 - casting
B23 - machine tools
B24 - grinding
B25 - hand tools
B26 - hand cutting tools
B27 - working or preserving wood or similar material
B28 - working cement, clay, or stone
B29 - working of plastics
B30 - presses
B31 - making articles of paper, cardboard or material worked in a manner analogous to paper
B32 - layered products
B33 - additive manufacturing technology
B41 - printing
B42 - bookbinding
B43 - writing or drawing implements
B44 - decorative arts
B60 - vehicles in general
B61 - railways
B62 - land vehicles for travelling otherwise than on rails
B63 - ships or other waterborne vessels
B64 - aircraft
B65 - conveying
B66 - hoisting
B67 - opening, closing {or cleaning} bottles, jars or similar containers
B68 - saddlery
B81 - microstructural technology
B82 - nanotechnology
B99 - subject matter not otherwise provided for in this section
C - chemistry
C01 - inorganic chemistry
C02 - treatment of water, waste water, sewage, or sludge
C03 - glass
C04 - cements
C05 - fertilisers
C06 - explosives
C07 - organic chemistry
C08 - organic macromolecular compounds
C09 - dyes
C10 - petroleum, gas or coke industries
C11 - animal or vegetable oils, fats, fatty substances or waxes
C12 - biochemistry
C13 - sugar industry
C14 - skins
C21 - metallurgy of iron
C22 - metallurgy
C23 - coating metallic material
C25 - electrolytic or electrophoretic processes
C30 - crystal growth
C40 - combinatorial technology
C99 - subject matter not otherwise provided for in this section
D - textiles
D01 - natural or man-made threads or fibres
D02 - yarns
D03 - weaving
D04 - braiding
D05 - sewing
D06 - treatment of textiles or the like
D07 - ropes
D10 - indexing scheme associated with sublasses of section d, relating to textiles
D21 - paper-making
D99 - subject matter not otherwise provided for in this section
E - fixed constructions
E01 - construction of roads, railways, or bridges
E02 - hydraulic engineering
E03 - water supply
E04 - building
E05 - locks
E06 - doors, windows, shutters, or roller blinds in general
E21 - earth drilling
E99 - subject matter not otherwise provided for in this section
F - mechanical engineering
F01 - machines or engines in general
F02 - combustion engines
F03 - machines or engines for liquids
F04 - positive - displacement machines for liquids
F05 - indexing schemes relating to engines or pumps in various subclasses of classes f01-f04
F15 - fluid-pressure actuators
F16 - engineering elements and units
F17 - storing or distributing gases or liquids
F21 - lighting
F22 - steam generation
F23 - combustion apparatus
F24 - heating
F25 - refrigeration or cooling
F26 - drying
F27 - furnaces
F28 - heat exchange in general
F41 - weapons
F42 - ammunition
F99 - subject matter not otherwise provided for in this section
G - physics
G01 - measuring
G02 - optics
G03 - photography
G04 - horology
G05 - controlling
G06 - computing
G07 - checking-devices
G08 - signalling
G09 - education
G10 - musical instruments
G11 - information storage
G12 - instrument details
G16 - information and communication technology [ict] specially adapted for specific application fields
G21 - nuclear physics
G99 - subject matter not otherwise provided for in this section
H - electricity
H01 - basic electric elements
H02 - generation
H03 - basic electronic circuitry
H04 - electric communication technique
H05 - electric techniques not otherwise provided for
H99 - subject matter not otherwise provided for in this section
Y - new / cross sectional technologies
Y02 - technologies or applications for mitigation or adaptation against climate change
Y04 - information or communication technologies having an impact on other technology areas
Y10 - technical subjects covered by former uspc

More Options ...

Title: Electrolytic process to produce sodium hypochlorite using sodium ion conductive ceramic membranes

Abstract

An electrochemical process for the production of sodium hypochlorite is disclosed. The process may potentially be used to produce sodium hypochlorite from seawater or low purity un-softened or NaCl-based salt solutions. The process utilizes a sodium ion conductive ceramic membrane, such as membranes based on NASICON-type materials, in an electrolytic cell. In the process, water is reduced at a cathode to form hydroxyl ions and hydrogen gas. Chloride ions from a sodium chloride solution are oxidized in the anolyte compartment to produce chlorine gas which reacts with water to produce hypochlorous and hydrochloric acid. Sodium ions are transported from the anolyte compartment to the catholyte compartment across the sodium ion conductive ceramic membrane. Sodium hydroxide is transported from the catholyte compartment to the anolyte compartment to produce sodium hypochlorite within the anolyte compartment.

Inventors:: Balagopal, Shekar; Malhotra, Vinod; Pendleton, Justin; Reid, Kathy Jo

Issue Date:: Tue Sep 18 00:00:00 EDT 2012

Research Org.:: Ceramatec, Inc. (Salt Lake City, UT)

Sponsoring Org.:: USDOE

OSTI Identifier:: 1078316

Patent Number(s):: 8268159

Application Number:: 11/613,857

Assignee:: Ceramatec, Inc. (Salt Lake City, UT)

Patent Classifications (CPCs):: C - CHEMISTRY C02 - TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE C02F - TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE

C - CHEMISTRY C25 - ELECTROLYTIC OR ELECTROPHORETIC PROCESSES C25B - ELECTROLYTIC OR ELECTROPHORETIC PROCESSES FOR THE PRODUCTION OF COMPOUNDS OR NON-METALS

Show more

C - CHEMISTRY C02 - TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE C02F - TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
C02F1/4674 - {with halogen or compound of halogens, e.g. chlorine, bromine}
C02F2001/46138 - {Electrodes comprising a substrate and a coating}
C02F2201/46115 - Electrolytic cell with membranes or diaphragms
C02F2201/46155 - Heating or cooling
C02F2209/02 - Temperature
C02F2209/06 - pH

C - CHEMISTRY C25 - ELECTROLYTIC OR ELECTROPHORETIC PROCESSES C25B - ELECTROLYTIC OR ELECTROPHORETIC PROCESSES FOR THE PRODUCTION OF COMPOUNDS OR NON-METALS
C25B1/26 - Chlorine
C25B13/04 - characterised by the material

Show less

DOE Contract Number:: FG02-05ER84221

Resource Type:: Patent

Country of Publication:: United States

Language:: English

Subject:: 37 INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY

Citation Formats


                    Balagopal, Shekar, Malhotra, Vinod, Pendleton, Justin, and Reid, Kathy Jo. Electrolytic process to produce sodium hypochlorite using sodium ion conductive ceramic membranes.  United States: N. p., 2012. 
        Web.

Copy to clipboard


                    Balagopal, Shekar, Malhotra, Vinod, Pendleton, Justin, & Reid, Kathy Jo. Electrolytic process to produce sodium hypochlorite using sodium ion conductive ceramic membranes.  United States.

Copy to clipboard


                    Balagopal, Shekar, Malhotra, Vinod, Pendleton, Justin, and Reid, Kathy Jo. Tue .  
        "Electrolytic process to produce sodium hypochlorite using sodium ion conductive ceramic membranes".  United States.  https://www.osti.gov/servlets/purl/1078316.

Copy to clipboard


                    
@article{osti_1078316,

  title        = {Electrolytic process to produce sodium hypochlorite using sodium ion conductive ceramic membranes},

  author       = {Balagopal, Shekar and Malhotra, Vinod and Pendleton, Justin and Reid, Kathy Jo},

  abstractNote = {An electrochemical process for the production of sodium hypochlorite is disclosed. The process may potentially be used to produce sodium hypochlorite from seawater or low purity un-softened or NaCl-based salt solutions. The process utilizes a sodium ion conductive ceramic membrane, such as membranes based on NASICON-type materials, in an electrolytic cell. In the process, water is reduced at a cathode to form hydroxyl ions and hydrogen gas. Chloride ions from a sodium chloride solution are oxidized in the anolyte compartment to produce chlorine gas which reacts with water to produce hypochlorous and hydrochloric acid. Sodium ions are transported from the anolyte compartment to the catholyte compartment across the sodium ion conductive ceramic membrane. Sodium hydroxide is transported from the catholyte compartment to the anolyte compartment to produce sodium hypochlorite within the anolyte compartment.},

  doi          = {},

  journal      = {},
number       = ,

  volume       = ,

  place        = {United States},

  year         = {Tue Sep 18 00:00:00 EDT 2012},

  month        = {Tue Sep 18 00:00:00 EDT 2012}

}

Copy to clipboard

Patent:

Save / Share:

Export Metadata

Save to My Library

Works referenced in this record:

Conduction paths in sintered ionic conductive material Na_1+xY_xZr_2−x(PO₄)₃
journal, October 1981

Fujitsu, Satoru; Nagai, Masayuki; Kanazawa, Takafumi
Materials Research Bulletin, Vol. 16, Issue 10, p. 1299-1309
https://doi.org/10.1016/0025-5408(81)90101-X

Crystal structures and crystal chemistry in the system Na1+xZr2SixP3−xO12
journal, February 1976

Hong, H. Y-P.
Materials Research Bulletin, Vol. 11, Issue 2
https://doi.org/10.1016/0025-5408(76)90073-8

Crystal chemistry of the Na_1+xZr_2−xL_x(PO₄)₃ (L = Cr, In, Yb) solid solutions
journal, March 1981

Delmas, C.; Olazcuaga, R.; Le Flem, G.
Materials Research Bulletin, Vol. 16, Issue 3, p. 285-290
https://doi.org/10.1016/0025-5408(81)90044-1

Fast Na+-ion transport in skeleton structures
journal, February 1976

Goodenough, J. B.; Hong, H. Y-P.; Kafalas, J. A.
Materials Research Bulletin, Vol. 11, Issue 2
https://doi.org/10.1016/0025-5408(76)90077-5

Compositional dependence of the electrochemical and structural parameters in the Nasicon system (Na1+xSixZr2P3−xO12)
journal, August 1981

Vonalpen, U.; Bell, M.; Hofer, H.
Solid State Ionics, Vol. 3-4
https://doi.org/10.1016/0167-2738(81)90085-0

Stoichiometry-structure-fast ion conduction in the nasicon solid solution
journal, September 1988

Boilot, J. P.; colomban, Ph.; Collin, G.
Solid State Ionics, Vol. 28-30
https://doi.org/10.1016/S0167-2738(88)80073-0

Electrodialysis in a non-aqueous medium: production of sodium methoxide
journal, May 1996

Sridhar, S.
Journal of Membrane Science, Vol. 113, Issue 1
https://doi.org/10.1016/0376-7388(95)00217-0

Chemistry and properties of solids with the [NZP] skeleton
journal, September 1993

Alamo, J.
Solid State Ionics, Vol. 63-65
https://doi.org/10.1016/0167-2738(93)90158-Y

Ionic conductivity of NASICON-type conductors Na1.5M0.5Zr1.5(PO4)3 (M:Al3+, Ga3+, Cr3+, Sc3+, Fe3+, In3+, Yb3+, Y3+)
journal, December 1992

Saito, Y.; Ado, K.; Asai, T.
Solid State Ionics, Vol. 58, Issue 3-4
https://doi.org/10.1016/0167-2738(92)90136-D

Ionic conductivity in sodium yttrium silicon oxide (Na5YSi4O12)-type silicates
journal, April 1978

Shannon, R. D.; Taylor, B. E.; Gier, T. E.
Inorganic Chemistry, Vol. 17, Issue 4
https://doi.org/10.1021/ic50182a033

Selective sodium removal from aqueous waste streams with NaSicon ceramics
journal, May 1999

Balagopal, S.; Landro, T.; Zecevic, S.
Separation and Purification Technology, Vol. 15, Issue 3
https://doi.org/10.1016/S1383-5866(98)00104-X

Ionic conductivity of NASICON-type Na1+xMxZr2−xP3O12 (M: Yb, Er, Dy)
journal, March 1996

Miyajima, Y.
Solid State Ionics, Vol. 84, Issue 1-2
https://doi.org/10.1016/S0167-2738(96)83006-2

Electrical conductivity and Ti4+ ion substitution range in NASICON system
journal, July 1995

Shimazu, K.
Solid State Ionics, Vol. 79
https://doi.org/10.1016/0167-2738(95)00038-8

The preparation and characterization of dense, highly conductive Na₅GdSi₄O₁₂ nasicon (NGS)
journal, December 1980

Bentzen, Janet J.; Nicholson, Patrick S.
Materials Research Bulletin, Vol. 15, Issue 12, p. 1737-1745
https://doi.org/10.1016/0025-5408(80)90191-9

Transport- und Umwandlungsprozesse bei der elektrochemischen Direktsynthese von Alkoholaten mittels Nafion-Membranen
journal, July 1992

Hamann, Carl Heinz; Theile, Volker; Koter, Stanislaw
Chemie Ingenieur Technik, Vol. 64, Issue 7
https://doi.org/10.1002/cite.330640718

Similar Records in DOE Patents and OSTI.GOV collections:

Electrolytic Process to Produce Sodium Hypochlorite Using NaSICON Ceramic Membranes

Technical Report Balagopal, Shekar
Method and system for producing hydrogen using sodium ion separation membranes

Patent Bingham, Dennis N; Klingler, Kerry M; Turner, Terry D; ...

A method of producing hydrogen from sodium hydroxide and water is disclosed. The method comprises separating sodium from a first aqueous sodium hydroxide stream in a sodium ion separator, feeding the sodium produced in the sodium ion separator to a sodium reactor, reacting the sodium in the sodium reactor with water, and producing a second aqueous sodium hydroxide stream and hydrogen. The method may also comprise reusing the second aqueous sodium hydroxide stream by combining the second aqueous sodium hydroxide stream with the first aqueous sodium hydroxide stream. A system of producing hydrogen is also disclosed.
Full Text Available
Process for degrading hypochlorite and sodium hypochlorite

Patent Huxtable, William P [Concord, TN]; Griffith, William L [Oak Ridge, TN]; Compere, Alicia L [Knoxville, TN]

A process for degrading hypochlorite waste and lithium hypochlorite solutions uses a cobalt oxide/molybdenum oxide catalyst formed from about 1-10 w/w % cobalt oxide and 1-15 w/w % molybdenum oxide disposed on a suitable substrate. The major advantage of the catalyst lies in its high degree of effectiveness and its very low cost.
Full Text Available
Reactive sintering of ceramic lithium ion electrolyte membranes

Patent Badding, Michael Edward; Dutta, Indrajit; Iyer, Sriram Rangarajan; ...

Disclosed herein are methods for making a solid lithium ion electrolyte membrane, the methods comprising combining a first reactant chosen from amorphous, glassy, or low melting temperature solid reactants with a second reactant chosen from refractory oxides to form a mixture; heating the mixture to a first temperature to form a homogenized composite, wherein the first temperature is between a glass transition temperature of the first reactant and a crystallization onset temperature of the mixture; milling the homogenized composite to form homogenized particles; casting the homogenized particles to form a green body; and sintering the green body at a secondmore » « less
Full Text Available
High conductivity NASICON electrolyte for room temperature solid-state sodium ion batteries

Patent Wachsman, Eric D.; Hitz, Gregory Thomas; Lee, Kang Taek

Solid electrolytes compositions, methods of making the solid electrolytes, and methods of using the solid electrolytes in batteries and other electrochemical technologies are disclosed. The method of producing a solid electrolyte comprises (a) ball milling Na2CO3, SiO2, NH4H2PO4, a zirconium source, and a dopant to produce a ball milled powder; (b) calcining the ball milled powder to produce a calcined powder; and (c) sintering the calcined powder to produce a solid electrolyte. The zirconium source for the solid electrolyte may be ZrO2. The dopant for the solid electrolyte may be AI2O3, Fe2O3, Sb2O3, Yb2O3, or Dy2O3.
Full Text Available

Similar Records

Title: Electrolytic process to produce sodium hypochlorite using sodium ion conductive ceramic membranes

Abstract

Citation Formats

Conduction paths in sintered ionic conductive material Na1+xYxZr2−x(PO4)3 journal, October 1981

Crystal structures and crystal chemistry in the system Na1+xZr2SixP3−xO12 journal, February 1976

Crystal chemistry of the Na1+xZr2−xLx(PO4)3 (L = Cr, In, Yb) solid solutions journal, March 1981

Fast Na+-ion transport in skeleton structures journal, February 1976

Compositional dependence of the electrochemical and structural parameters in the Nasicon system (Na1+xSixZr2P3−xO12) journal, August 1981

Stoichiometry-structure-fast ion conduction in the nasicon solid solution journal, September 1988

Electrodialysis in a non-aqueous medium: production of sodium methoxide journal, May 1996

Chemistry and properties of solids with the [NZP] skeleton journal, September 1993

Ionic conductivity of NASICON-type conductors Na1.5M0.5Zr1.5(PO4)3 (M:Al3+, Ga3+, Cr3+, Sc3+, Fe3+, In3+, Yb3+, Y3+) journal, December 1992

Ionic conductivity in sodium yttrium silicon oxide (Na5YSi4O12)-type silicates journal, April 1978

Selective sodium removal from aqueous waste streams with NaSicon ceramics journal, May 1999

Ionic conductivity of NASICON-type Na1+xMxZr2−xP3O12 (M: Yb, Er, Dy) journal, March 1996

Electrical conductivity and Ti4+ ion substitution range in NASICON system journal, July 1995

The preparation and characterization of dense, highly conductive Na5GdSi4O12 nasicon (NGS) journal, December 1980

Transport- und Umwandlungsprozesse bei der elektrochemischen Direktsynthese von Alkoholaten mittels Nafion-Membranen journal, July 1992

Conduction paths in sintered ionic conductive material Na_1+xY_xZr_2−x(PO₄)₃
journal, October 1981

Crystal structures and crystal chemistry in the system Na1+xZr2SixP3−xO12
journal, February 1976

Crystal chemistry of the Na_1+xZr_2−xL_x(PO₄)₃ (L = Cr, In, Yb) solid solutions
journal, March 1981

Fast Na+-ion transport in skeleton structures
journal, February 1976

Compositional dependence of the electrochemical and structural parameters in the Nasicon system (Na1+xSixZr2P3−xO12)
journal, August 1981

Stoichiometry-structure-fast ion conduction in the nasicon solid solution
journal, September 1988

Electrodialysis in a non-aqueous medium: production of sodium methoxide
journal, May 1996

Chemistry and properties of solids with the [NZP] skeleton
journal, September 1993

Ionic conductivity of NASICON-type conductors Na1.5M0.5Zr1.5(PO4)3 (M:Al3+, Ga3+, Cr3+, Sc3+, Fe3+, In3+, Yb3+, Y3+)
journal, December 1992

Ionic conductivity in sodium yttrium silicon oxide (Na5YSi4O12)-type silicates
journal, April 1978

Selective sodium removal from aqueous waste streams with NaSicon ceramics
journal, May 1999

Ionic conductivity of NASICON-type Na1+xMxZr2−xP3O12 (M: Yb, Er, Dy)
journal, March 1996

Electrical conductivity and Ti4+ ion substitution range in NASICON system
journal, July 1995

The preparation and characterization of dense, highly conductive Na₅GdSi₄O₁₂ nasicon (NGS)
journal, December 1980

Transport- und Umwandlungsprozesse bei der elektrochemischen Direktsynthese von Alkoholaten mittels Nafion-Membranen
journal, July 1992