Patents by Inventor Robert J. Gulotty, Jr.
Robert J. Gulotty, Jr. has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).
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Patent number: 11840670Abstract: Methods of catalytic hydrogenation, including methods that may be used to hydrogenate an unsaturated reactant to produce an at least partially saturated product that may be a solid at 20° C. Systems for catalytic hydrogenation that may include a reactor bed containing one or more activated carbon monolith catalysts. At least 97% of unsaturated bonds may be saturated by the methods and systems.Type: GrantFiled: December 3, 2021Date of Patent: December 12, 2023Assignee: Applied Technology Limited PartnershipInventors: Robert J. Gulotty, Jr., Kelsey Abner, Myranda Jackson
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Publication number: 20220195312Abstract: Methods of catalytic hydrogenation, including methods that may be used to hydrogenate an unsaturated reactant to produce an at least partially saturated product that may be a solid at 20° C. Systems for catalytic hydrogenation that may include a reactor bed containing one or more activated carbon monolith catalysts. At least 97% of unsaturated bonds may be saturated by the methods and systems.Type: ApplicationFiled: December 3, 2021Publication date: June 23, 2022Inventors: Robert J. Gulotty, JR., Kelsey Abner, Myranda Jackson
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Patent number: 10471338Abstract: This invention is a novel word forming board game that uses a unique combination of features that enables and rewards large word formation. In addition, chance is used to make the outcome less predictable and more fun for players of all skill levels. The game apparatus includes a larger number of board spaces, a large number of letter tiles, and chance components (multiplier, bonus word, swap card and swap tiles chance types). The method of play uses a large number of letter tiles per player hand, and the ability to exchange letter tiles at the end of each turn. The basis of the word points is the word length which rewards large word formation. The multiplier chance types amplify the impact of forming large words on the player score, with multiplier values as high as 10 and as low as ?10, distributed so lesser skilled players can win more often.Type: GrantFiled: December 26, 2017Date of Patent: November 12, 2019Inventor: Robert J. Gulotty, Jr.
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Publication number: 20180169511Abstract: This invention is a novel word forming board game that uses a unique combination of features that enables and rewards large word formation. In addition, chance is used to make the outcome less predictable and more fun for players of all skill levels. The game apparatus includes a larger number of board spaces, a large number of letter tiles, and chance components (multiplier, bonus word, swap card and swap tiles chance types). The method of play uses a large number of letter tiles per player hand, and the ability to exchange letter tiles at the end of each turn. The basis of the word points is the word length which rewards large word formation. The multiplier chance types amplify the impact of forming large words on the player score, with multiplier values as high as 10 and as low as ?10, distributed so lesser skilled players can win more often.Type: ApplicationFiled: December 26, 2017Publication date: June 21, 2018Inventor: Robert J. Gulotty, JR.
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Publication number: 20180147482Abstract: This invention is a novel game that combines player skills in forming large words, strategy and chance. The game utilizes physical or virtual single letter tiles, a game board and chance types as game components. The goal of the game is to get the most points. Letter tiles are used to create words and points are assigned for these words based on the product of the number of letters in the word and the number on a multiplier chance type. Multiplier chance types can be positive or negative whole numbers, or zero. Large words can be easily made from a large number of letter tiles per player turn, a large pool of letter tiles, and a large number of spaces on the board. Bonus word, swap tile and bankrupt chance types add chance to the player scores. The chance types make the game more enjoyable than other word forming games.Type: ApplicationFiled: November 26, 2016Publication date: May 31, 2018Inventor: Robert J. Gulotty, JR.
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Publication number: 20170015609Abstract: A catalyst support for manufacturing a mixture of alcohols from synthesis gas comprises a combination of nickel, molybdenum, at least one metal selected from the group consisting of palladium, ruthenium, chromium, gold, zirconium, and aluminum, and at least one of an alkali metal or alkaline earth series metal as a promoter. The catalyst may be used in a process for converting synthesis gas wherein the primary product is a mixture of ethanol (EtOH), propanol (PrOH), and butanol (BuOH), optionally in conjunction with higher alcohols.Type: ApplicationFiled: September 29, 2016Publication date: January 19, 2017Inventors: Dean M. Millar, Mark H. McAdon, Robert J. Gulotty, JR., David G. Barton, Daniela Ferrari, Billy Brian Bardin, Yu Liu
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Patent number: 9415375Abstract: Catalyst compositions for producing mixed alcohols from a synthesis gas feed. The catalyst composition comprises a catalytic metal combination on a catalyst support, a first optional promoter and a second optional promoter, where the catalytic metal combination consists essentially of iridium, vanadium, and molybdenum.Type: GrantFiled: March 30, 2011Date of Patent: August 16, 2016Assignee: Dow Global Technologies LLCInventors: Daniela Ferrari, Neelesh J. Rane, Adam Chojecki, Gerolamo Budroni, David G. Barton, Mark H. McAdon, Robert J. Gulotty, Jr., Dean M. Millar, Palanichamy Manikandan
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Patent number: 9233367Abstract: A process for preparing a molybdenum sulfide-based catalyst comprises drying a precipitated molybdenum sulfide-based catalyst precursor, for example, a wet filter cake, such that a particulate catalyst precursor, containing from 12 to 15 percent by weight water, is formed. The particulate catalyst precursor is desirably in the form of free-flowing particles. The particulate catalyst precursor is then auto-reduced. A rotary furnace that subjects the catalyst precursor to at least two zones having distinct temperatures may be conveniently used for drying, auto-reduction, or both. The staged drying and auto-reduction steps reduce the tendency of the precursor to self-heat, which is undesirable because it reduces both the activity and selectivity of the final catalyst.Type: GrantFiled: April 1, 2011Date of Patent: January 12, 2016Assignee: Dow Global Technologies LLCInventors: Robert J. Gulotty, Jr., Dean M. Millar, Albert E. Schweizer, Jr., Raymond M. Collins
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Publication number: 20150139890Abstract: A process for preparing a molybdenum sulfide-based catalyst comprises drying a precipitated molybdenum sulfide-based catalyst precursor, for example, a wet filter cake, such that a particulate catalyst precursor, containing from 12 to 15 percent by weight water, is formed. The particulate catalyst precursor is desirably in the form of free-flowing particles. The particulate catalyst precursor is then auto-reduced. A rotary furnace that subjects the catalyst precursor to at least two zones having distinct temperatures may be conveniently used for drying, auto-reduction, or both. The staged drying and auto-reduction steps reduce the tendency of the precursor to self-heat, which is undesirable because it reduces both the activity and selectivity of the final catalyst.Type: ApplicationFiled: April 1, 2011Publication date: May 21, 2015Applicant: DOW GLOBAL TECHNOLOGIES LLCInventors: Robert J. Gulotty, JR., Dean Millar, Albert E. Schweizer, JR., Raymond M. Collins
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Publication number: 20140018453Abstract: A catalyst for manufacturing a mixture of alcohols from synthesis gas comprises a combination of nickel, molybdenum, at least one metal selected from the group consisting of palladium, ruthenium, chromium, gold, zirconium, and aluminium, and at least one of an alkali metal or alkaline earth series metal as a promoter. The catalyst may be used in a process for converting synthesis gas wherein the primary product is a mixture of ethanol (EtOH), propanol (PrOH), and butanol (BuOH), optionally in conjunction with higher alcohols.Type: ApplicationFiled: April 1, 2011Publication date: January 16, 2014Applicant: DOW GLOBAL TECHNOLOGIES LLCInventors: Dean M Millar, Mark H. McAdon, Robert J. Gulotty, Jr., David G. Barton, Daniela Ferrari, Billy B. Bardin, Yu Liu
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Publication number: 20140018452Abstract: A catalyst suitable for manufacturing a mixture of alcohols from synthesis gas comprises a combination of nickel, two or more metals selected from ruthenium, palladium, gold, chromium, aluminum and tin, and at least one of an alkali metal or alkaline earth series metal as a promoter. The catalyst may be used in a process for converting synthesis gas wherein the primary product is a mixture of ethanol (EtOH), propanol (PrOH), and butanol (BuOH), optionally in conjunction with higher alcohols.Type: ApplicationFiled: April 1, 2011Publication date: January 16, 2014Applicant: DOW GLOBAL TECHNOLOGIES LLCInventors: Dean Millar, Mark H. McAdon, Robert J. Gulotty,, JR., David G. Barton, Daniela Ferrari, Billy B. Bardin, Yu Liu
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Patent number: 8558027Abstract: The present disclosure relates to compositions, systems, and methods of forming an amine (e.g., methylenedianiline (MDA)) using an acid catalyst including, for example, a metal oxide-silica catalyst calcined at temperature(s) of about ?500° C. to form a solid acid silica-metal oxide catalyst. A metal oxide of a solid acid silica-metal oxide catalyst may comprise alumina. A process for making a solid acid silica-metal oxide catalyst may comprise calcining an amorphous alumina-silica material at temperature(s) of about ?500° C. and/or under an anhydrous and/or inert atmosphere. A rearrangement reaction of the condensation product of aniline and formaldehyde in the presence of a solid acid silica-metal oxide catalyst may yield more MDA and/or more desirable isomer(s) of MDA than reactions performed with a corresponding catalyst calcined at temperature(s) of less than 500° C.Type: GrantFiled: August 14, 2009Date of Patent: October 15, 2013Assignee: Dow Global Technologies Inc.Inventors: Heiko Weiner, David C. Molzahn, Robert J. Gulotty, Jr.
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Publication number: 20130029841Abstract: Catalyst compositions for producing mixed alcohols from a synthesis gas feed. The catalyst composition comprises a catalytic metal combination on a catalyst support, a first optional promoter and a second optional promoter, where the catalytic metal combination consists essentially of iridium, vanadium, and molybdenum.Type: ApplicationFiled: March 30, 2011Publication date: January 31, 2013Applicant: DOW GLOBAL TECHNOLOGIES LLCInventors: Daniela Ferrari, Neelesh J. Rane, Adam Chojecki, Gerolamo Budroni, David G. Barton, Mark H. McAdon, Robert J. Gulotty, JR., Dean M. Millar, Palanichamy Manikandan
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Publication number: 20120208695Abstract: A supported catalyst composition suitable for use in converting synthesis gas to alcohols comprises a catalytic metal, a catalyst promoter and a catalyst support.Type: ApplicationFiled: November 2, 2010Publication date: August 16, 2012Applicant: Dow Global Technologies LLCInventors: Billy B. Bardin, David G. Barton, Adam Chojecki, Howard W. Clark, Daniela Ferrari, Robert J. Gulotty, JR., Yu Liu, Mark H. McAdon, Dean M. Millar, Neelesh Rane, Hendrik E. Tuinstra
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Publication number: 20110144368Abstract: The present disclosure relates to compositions, systems, and methods of forming an amine (e.g., methylenedianiline (MDA)) using an acid catalyst including, for example, a metal oxide-silica catalyst calcined at temperature(s) of about ?500° C. to form a solid acid silica-metal oxide catalyst. A metal oxide of a solid acid silica-metal oxide catalyst may comprise alumina. A process for making a solid acid silica-metal oxide catalyst may comprise calcining an amorphous alumina-silica material at temperature(s) of about ?500° C. and/or under an anhydrous and/or inert atmosphere. A rearrangement reaction of the condensation product of aniline and formaldehyde in the presence of a solid acid silica-metal oxide catalyst may yield more MDA and/or more desirable isomer(s) of MDA than reactions performed with a corresponding catalyst calcined at temperature(s) of less than 500° C.Type: ApplicationFiled: August 14, 2009Publication date: June 16, 2011Inventors: Heiko Weiner, David C. Molzahn, Robert J. Gulotty, JR.
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Publication number: 20100312029Abstract: A method for dehydroaromatizing methane by contacting a feedstream that contains methane, in a circulating fluid bed reactor/regenerator, with a catalyst and under conditions sufficient to dehydroaromatize methane and produce at least one liquid aromatic compound such as benzene, toluene or naphthalene and hydrogenated products such as cyclohexane and decahydronaphthalene. The method may also be used to produce hydrogen. The feedstream may be a natural gas feedstock. The method may include one step and two step catalyst regeneration.Type: ApplicationFiled: November 17, 2008Publication date: December 9, 2010Applicant: Dow Global Technologies Inc.Inventors: Robert J. Gulotty, JR., Joseph E. Pelati, Arthur R. Prunier, JR., Albert E. Schweizer, JR.
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Patent number: 6821924Abstract: An oxidative halogenation process involving contacting a hydrocarbon, for example, ethylene, or a halogenated hydrocarbon with a source of halogen, such as hydrogen chloride, and a source of oxygen in the presence of a catalyst so as to form a halocarbon, preferably a chlorocarbon, having a greater number of halogen substituents than the starting hydrocarbon or halogenated hydrocarbon, for example, 1,2-dichloroethane. The catalyst is a novel composition comprising copper dispersed on a porous rare earth halide support, preferably, a porous rare earth chloride support. A catalyst precursor composition comprising copper dispersed on a porous rare earth oxyhalide support is disclosed. Use of the porous rare earth halide and oxyhalide as support materials for catalytic components is disclosed.Type: GrantFiled: November 12, 2003Date of Patent: November 23, 2004Assignee: Dow Global Technologies Inc.Inventors: Robert J. Gulotty, Jr., Mark E. Jones, Daniel A. Hickman
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Patent number: 6680415Abstract: An oxidative halogenation process involving contacting a hydrocarbon, for example, ethylene, or a halogenated hydrocarbon with a source of halogen, such as hydrogen chloride, and a source of oxygen in the presence of a catalyst so as to form a halocarbon, preferably a chlorocarbon, having a greater number of halogen substituents than the starting hydrocarbon or halogenated hydrocarbon, for example, 1,2-dichloroethane. The catalyst is a novel composition comprising copper dispersed on a porous rare earth halide support, preferably, a porous rare earth chloride support. A catalyst precursor composition comprising copper dispersed on a porous rare earth oxyhalide support is disclosed. Use of the porous rare earth halide and oxyhalide as support materials for catalytic components is disclosed.Type: GrantFiled: May 14, 2002Date of Patent: January 20, 2004Assignee: Dow Global Technologies Inc.Inventors: Robert J. Gulotty, Jr., Mark E. Jones, Daniel A. Hickman
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Patent number: 6388048Abstract: Metal [hexacyanocobaltate, cobalthexanitrite nitroferricyanide] complexes are useful alkylene oxide polymerization catalysts. The metal is any that forms a precipitate with the hexacyanocobaltate, cobalthexanitrite and nitroferricyanide groups. These catalysts are made from less expensive raw materials than the common zinc hexacyanocobaltate catalysts, and provide short induction periods and many cases more controlled exotherms. In addition, the metal [hexacyanocobaltate, cobalthexanitrite nitroferricyanide] catalysts often provide poly(propylene oxide) polymers having very low unsaturations, even when the catalyst is complexed with a complexing agent such as glyme.Type: GrantFiled: May 19, 2000Date of Patent: May 14, 2002Assignee: The Dow Chemical CompanyInventors: David E. Laycock, Kendra L. Flagler, Robert J. Gulotty, Jr.
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Patent number: 6384183Abstract: Metal hexacyanocobaltate nitroferricyanide catalysts are active polymerization catalysts for alkylene oxides. These catalysts tend to have short induction periods, followed by rapid polymerization of alkylene oxides to polyethers.Type: GrantFiled: May 19, 2000Date of Patent: May 7, 2002Assignee: The Dow Chemical CompanyInventors: David E. Laycock, Kendra L. Flagler, Robert J. Gulotty, Jr.