Patents by Inventor John M. Brupbacher
John M. Brupbacher 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: 9162514Abstract: A method includes producing an article having a substrate with a plurality of independent taggant layers that each include metal oxide nanocrystals doped with at least one Lanthanide element. Each taggant layer includes metal oxide nanocrystals doped with a different Lanthanide element than each other taggant layer.Type: GrantFiled: October 22, 2014Date of Patent: October 20, 2015Assignee: The Johns Hopkins UniversityInventors: Morgana M. Trexler, Dajie Zhang, Lisa A. Kelly, Jennifer L. Sample, John M. Brupbacher
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Publication number: 20150283846Abstract: A method includes producing an article having a substrate with a plurality of independent taggant layers that each include metal oxide nanocrystals doped with at least one Lanthanide element. Each taggant layer includes metal oxide nanocrystals doped with a different Lanthanide element than each other taggant layer.Type: ApplicationFiled: October 22, 2014Publication date: October 8, 2015Inventors: Morgana M. Trexler, Dajie Zhang, Lisa A. Kelly, Jennifer L. Sample, John M. Brupbacher
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Patent number: 8895158Abstract: An article includes a substrate with a plurality of independent taggant layers that each include metal oxide nanocrystals doped with at least one Lanthanide element. Each taggant layer includes metal oxide nanocrystals doped with a different Lanthanide element than each other taggant layer.Type: GrantFiled: August 3, 2012Date of Patent: November 25, 2014Assignee: The Johns Hopkins UniversityInventors: Morgana M. Trexler, Dajie Zhang, Lisa A. Kelly, Jennifer L. Sample, John M. Brupbacher
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Publication number: 20130040150Abstract: An article includes a substrate with a plurality of independent taggant layers that each include metal oxide nanocrystals doped with at least one Lanthanide element. Each taggant layer includes metal oxide nanocrystals doped with a different Lanthanide element than each other taggant layer.Type: ApplicationFiled: August 3, 2012Publication date: February 14, 2013Applicant: THE JOHNS HOPKINS UNIVERSITYInventors: Morgana M. Trexler, Dajie Zhang, Lisa A. Kelly, Jennifer L. Sample, John M. Brupbacher
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Patent number: 6790526Abstract: Novel appliqués comprising oxyhalopolymer-adhesive composites wherein the adhesive layer of the composite is chemically bonded to reactive sites on at least one side of the oxyhalopolymer layer, possess superior peel strengths, resistance to delamination and protective properties, including protection of surfaces from lightning strike to seamless protective liners for tanks. The appliques are suitable for printing architectural designs thereon. Multilayered specialty appliqués can be fabricated from the above fundamental oxyhalopolymer-adhesive composite structure, including layered adhesives for encapsulating tridimensional mechanical and electrical devices, such as RF, or microwave sensitive antennae for transmitting and receiving communications, providing protection from environmental electromagnetic effects (E3), shock and impact resistance, multidimensional deformable structures; housing for temperature control systems, etc.Type: GrantFiled: August 2, 2002Date of Patent: September 14, 2004Assignee: Integument Technologies, Inc.Inventors: Terrence G. Vargo, Timothy S. Koloski, John M. Brupbacher, Andrew W. Dalgleish, Garner S. Holdsworth
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Patent number: 6648167Abstract: A substrate protected by a polymeric lining wherein passageways are provided between the lining and the substrate for channeling of fluids which may penetrate through the lining to the substrate surface. In one embodiment the lining is formed to provide for passages between the lining and the substrate. Mesh attached to the substrate provides for securement of the lining to the substrate by at least partial embedment of the mesh within the lining. Wire spacers are positioned between the mesh and the substrate to separate portions of the lining from the substrate surface and form passageways for channeling fluid which may penetrate the lining. In another embodiment a vessel includes a network of spacers forming a generally parallel array of passageways and at least one passageway transverse to the parallel array of passageways.Type: GrantFiled: February 14, 2001Date of Patent: November 18, 2003Assignee: Sermatech International, Inc.Inventors: John M. Brupbacher, Scott E. Vogt
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Publication number: 20030152766Abstract: Novel appliqués comprising oxyhalopolymer-adhesive composites wherein the adhesive layer of the composite is chemically bonded to reactive sites on at least one side of the oxyhalopolymer layer, possess superior peel strengths, resistance to delamination and protective properties, including protection of surfaces from lightning strike to seamless protective liners for tanks. The appliques are suitable for printing architectural designs thereon. Multilayered specialty appliqués can be fabricated from the above fundamental oxyhalopolymer-adhesive composite structure, including layered adhesives for encapsulating tridimensional mechanical and electrical devices, such as RF, or microwave sensitive antennae for transmitting and receiving communications, providing protection from environmental electromagnetic effects (E3), shock and impact resistance, multidimensional deformable structures; housing for temperature control systems, etc.Type: ApplicationFiled: August 2, 2002Publication date: August 14, 2003Inventors: Terrence G. Vargo, Timothy S. Koloski, John M. Brupbacher, Andrew W. Dalgleish, Garner S. Holdsworth
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Publication number: 20030049485Abstract: The present invention provides long-lived corrosion resistant coatings for metal substrates. The coatings comprise a chemically stable mechanical attachment interface formed by coating a metal substrate with a seamless thermal spray metallic coating of a Ni-based alloy or stainless steel, and a polymer layer bonded to the metallic interface. The coatings are suited for resisting corrosive environments in process chemistry vessels, furnaces and boilers.Type: ApplicationFiled: September 6, 2001Publication date: March 13, 2003Inventors: John M. Brupbacher, Mark F. Mosser, Scott E. Vogt
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Patent number: 5217816Abstract: A method is taught for the in-situ precipitation of ceramic materials in a metal matrix. By means of the solvent assisted reaction, metal-ceramic composites having highly superior properties may be obtained. The invention involves the reaction of the ceramic forming constituents in a metal solvent medium to provide very finely-dispersed ceramic particles in the metal matrix. Exemplary materials include titanium diboride in an aluminum matrix.Type: GrantFiled: September 4, 1991Date of Patent: June 8, 1993Assignee: Martin Marietta CorporationInventors: John M. Brupbacher, Leontios Christodoulou, Dennis C. Nagle
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Patent number: 5212343Abstract: Devices and methods are disclosed for contacting a hot reaction mass with water to initiate an explosive reaction. The reaction mass comprises a ceramic or intermetallic material that is produced by exothermically reacting a mixture of reactive elements. Suitable reaction masses include borides and/or carbides that are formed by reacting a mixture comprising B and/or C in combination with an element selected from Ti, V, Cr, Zr, Nb, Mo, Hf, Ta and W. Additional metals such as Al, Li, Mg, Zn, Cu, Be, Na, K, Ca, Rb, Y, U and Cs may also be present in the reactive mixture. In operation, the hot reaction mass is contacted with water to initiate an explosive water reaction and to produce large volumes of hydrogen containing gas.Type: GrantFiled: August 27, 1990Date of Patent: May 18, 1993Assignee: Martin Marietta CorporationInventors: John M. Brupbacher, Leontios Christodoulou, James M. Patton, Russell N. Bennett, Alvin F. Bopp, Larry G. Boxall, William M. Buchta
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Patent number: 5093148Abstract: An arc-melting method is taught for the formation of metallic-second phase composite materials. The method involves the formation of an intermediate composite material comprising a relatively high loading of second phase particles dispersed in a metal matrix. This intermediate material is then combined with an additional amount of metal and arc-melted to form a final composite comprising a lower loading of the second phase particles dispersed in a final metallic matrix. The final metallic matrix may be comprised of a metal, metal alloy, or intermetallic, while the second phase particles may comprise ceramic materials such as borides, carbides, nitrides, silicides, oxides or sulfides.Type: GrantFiled: July 10, 1991Date of Patent: March 3, 1992Assignee: Martin Marietta CorporationInventors: Leontios Christodoulou, Dennis C. Nagle, John M. Brupbacher
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Patent number: 5059490Abstract: The present invention relates to the formation of whisker reinforced metal matrix composites in which complex boride or carbide whiskers having an aspect ratio of greater than 10:1 are distributed throughout a metal, metal alloy, or intermetallic matrix. Exemplary complex boride whiskers include TiNbB, TiTaB, TiVB, NbHfB, and TiNbMoB. Exemplary complex carbide whiskers include TiNbC, TiVC, TiZrC, TiHfC, and TiTaC. A method for the in-situ formation of complex boride and complex carbide whiskers within metallic matrices is disclosed which involves reacting a mixture of individual complex ceramic-forming constituents in the presence of a metal to precipitate the desired complex ceramic whiskers in a metal matrix.Type: GrantFiled: June 15, 1989Date of Patent: October 22, 1991Assignee: Martin Marietta CorporationInventors: John M. Brupbacher, Leontios Christodoulou, Dennis C. Nagle
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Patent number: 5015534Abstract: This invention relates to a rapidly solidified product comprising a second phase in both a stable particulate form and a metastable flake form dispersed in an intermetallic matrix.Type: GrantFiled: August 30, 1989Date of Patent: May 14, 1991Assignee: Martin Marietta CorporationInventors: Stephen L. Kampe, John M. Brupbacher, Leontios Christodoulou, Dennis C. Nagle
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Patent number: 4985202Abstract: A method is taught for the in-situ precipitation of second phase materials, such as ceramic or intermetallic particles, in a substantial volume fraction of solvent metal matrix. The invention involves the propagating reaction of the second phase-forming constituents in a solvent metal medium to provide a porous composite of finely-dispersed second phase particles in the metal matrix. Exemplary materials include titanium carbide or titanium diboride in an aluminum matrix.Type: GrantFiled: August 28, 1989Date of Patent: January 15, 1991Assignee: Martin Marietta CorporationInventors: William C. Moshier, John M. Brupbacher, Leontios Christodoulou, Dennis C. Nagle
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Patent number: 4921531Abstract: The present invention relates to a process for the production of fine powder materials and the products of that process. The process involves the in-situ precipitation of second phase particles, such as ceramic or intermetalics, within a metal matrix, followed by separation of the particles from the matrix to yield a powder comprising the second phase particles. Particles formed by this process are typically in the size range of 0.01 to 10 microns and have controlled morphology, narrow size distribution, well defined stoichiometery and relatively high purity. Exemplary of second phase particles formed by this process are metal borides, carbides, nitrides, oxides, silicides and beryllides, including TiB.sub.2, ZrB.sub.2, VB.sub.2, MoB.sub.2, TiC, WC, VC, TiN, ZrSi.sub.2, MoSi.sub.2, Ti.sub.5 Si.sub.3, and TiBe.sub.12.Type: GrantFiled: August 30, 1989Date of Patent: May 1, 1990Assignee: Martin Marietta CorporationInventors: Dennis C. Nagle, John M. Brupbacher, Leontios Christodoulou
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Patent number: 4917964Abstract: A method is taught for the in-situ precipitation of second phase materials, such as ceramic or intermetallic particles, in a substantial volume fraction of solvent metal matrix. The invention involves the propagating reaction of the second phase-forming constituents in a solvent metal medium to provide a porous composite of finely-dispersed second phase particles in the metal matrix. Exemplary materials include titanium carbide or titanium diboride in an aluminum matrix.Type: GrantFiled: August 30, 1989Date of Patent: April 17, 1990Assignee: Martin Marietta CorporationInventors: William C. Moshier, John M. Brupbacher, Leontios Christodoulou, Dennis C. Nagle
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Patent number: 4915903Abstract: A method is taught for the formation of intermetallic-second phase composite materials. The method involves the formation of a first metal-second phase composite comprising a relatively high loading of discrete, second phase particles distributed throughout a metal matrix, dilution of the first composite into an additional amount of metal to form a second composite comprising a lower loading of second phase particles within an intermediate metal matrix, and introduction of the second composite into another metal which is reactive with the intermediate metal matrix of the composite to form an intermetallic. A final intermetallic-second phase composite is thereby formed comprising a dispersion of discrete second phase particles throughout a final intermetallic matrix. The final intermetallic matrix may comprise a wide variety of intermetallic materials, with particular emphasis drawn to the aluminides and silicides. Exemplary intermetallics include Ti.sub.3 Al, TiAl, TiAl.sub.3, Ni.sub.3 Al, NiAl, Nb.sub.Type: GrantFiled: May 5, 1988Date of Patent: April 10, 1990Assignee: Martin Marietta CorporationInventors: John M. Brupbacher, Leontios Christodoulou, Dennis C. Nagle
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Patent number: 4916029Abstract: This invention relates to a composite material comprising an in-situ precipitated second phase in an intermetallic matrix, and to the process for making such a composite.Type: GrantFiled: September 29, 1987Date of Patent: April 10, 1990Assignee: Martin Marietta CorporationInventors: Dennis C. Nagle, John M. Brupbacher, Leontios Christodoulou
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Patent number: 4915902Abstract: The present invention relates to the formation of whisker reinforced metal matrix composites in which complex boride or carbide whiskers are distributed throughout a metal, metal alloy, or intermetallic matrix. Exemplary complex boride whiskers include TiNbB, TiTaB, TiVB, NbHfB, and TiNbMoB. Exemplary complex carbide whiskers include TiNbC, TiVC, TiZrC, TiHfC, and TiTaC. A method for the in-situ formation of complex boride and complex carbide whiskers within metallic matrices is disclosed which involves reacting a mixture of individual complex ceramic-forming constituents in the presence of a metal to precipitate the desired complex ceramic whiskers in a metal matrix.Type: GrantFiled: February 17, 1988Date of Patent: April 10, 1990Assignee: Martin Marietta CorporationInventors: John M. Brupbacher, Leontios Christodoulou, Dennis C. Nagle
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Patent number: 4915908Abstract: A method is taught for the in-situ precipitation of second phase materials, such as ceramic or intermetallic particles, in a metallic matrix. By means of the Direct Addition Process, metal-second phase composites having highly superior properties may be obtained. Compacts of second phase-forming constituents and solvent metal are directly added to a molten metal bath to precipitate the second phase in-situ. Exemplary materials include titanium diboride or titanium carbide in an aluminum matrix.Type: GrantFiled: November 5, 1986Date of Patent: April 10, 1990Assignee: Martin Marietta CorporationInventors: Dennis C. Nagle, John M. Brupbacher, Leontios Christodoulou