Patents Assigned to Fahs Stagemyer, LLC
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Patent number: 10287193Abstract: A system has been developed to treat ballast water by selectively dissociating target molecules into component products compositionally distinct from the target molecule, wherein the bonds of the target molecule do not reform because the components are no longer reactive with each other. Dissociation is affected by treating the target molecule with light at a frequency and intensity, alone or in combination with a catalyst in an amount effective to selectively break bonds within the target molecule. Dissociation does not result in re-association into the target molecule by the reverse process, and does not produce component products which have a change in oxidation number or state incorporated oxygen or other additives because the process does not proceed via a typical reduction-oxidation mechanism.Type: GrantFiled: February 25, 2013Date of Patent: May 14, 2019Assignee: FAHS STAGEMYER LLCInventors: Richard W. Fahs, Matthew D. W. Fahs
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Patent number: 9334183Abstract: A process has been developed to selectively dissociate target molecules into component products compositionally distinct from the target molecule, wherein the bonds of the target molecule do not reform because the components are no longer reactive with each other. Dissociation is affected by treating the target molecule with light at a frequency and intensity, alone or in combination with a catalyst in an amount effective to selectively break bonds within the target molecule. Dissociation does not result in re-association into the target molecule by the reverse process, and does not produce component products which have a change in oxidation number or state incorporated oxygen or other additives because the process does not proceed via a typical reduction-oxidation mechanism. This process can be used for the remediation of water, particularly ballast water.Type: GrantFiled: July 2, 2015Date of Patent: May 10, 2016Assignee: Fahs Stagemyer, LLCInventors: Richard W. Fahs, II, Matthew D. W. Fahs
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Patent number: 9073766Abstract: A process has been developed to selectively dissociate target molecules into component products compositionally distinct from the target molecule, wherein the bonds of the target molecule do not reform because the components are no longer reactive with each other. Dissociation is affected by treating the target molecule with light at a frequency and intensity, alone or in combination with a catalyst in an amount effective to selectively break bonds within the target molecule. Dissociation does not result in re-association into the target molecule by the reverse process, and does not produce component products which have a change in oxidation number or state incorporated oxygen or other additives because the process does not proceed via a typical reduction-oxidation mechanism. This process can be used for the remediation of water, particularly ballast water.Type: GrantFiled: February 24, 2012Date of Patent: July 7, 2015Assignee: Fahs Stagemyer, LLCInventors: Richard W. Fahs, II, Matthew D. W. Fahs
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Publication number: 20140154597Abstract: Anodes utilizing precise energy separation are provided. The anodes can be used to generate electrical energy from a feedstock via precise energy separation. The anodes include an energy source that supplies the promoter energy to target molecules in a feedstock to dissociate one or more target bonds in one or more target molecules. Generally, the energy is provided in an effective amount, intensity, and frequency of energy to specifically dissociate one or more target bonds in one or more target molecule present in the feedstock, releasing electrons. These electrons are accepted by an electrode that is electrically connected to an electron sink. Fuel cells containing anodes utilizing precise energy separation are provided.Type: ApplicationFiled: December 4, 2013Publication date: June 5, 2014Applicant: Fahs Stagemyer LLCInventor: Richard W. Fahs, II
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Publication number: 20140110351Abstract: Internally activated energy distribution guides for use in clear to turbid liquids or air have been developed. An external energy source is transferred to a matrix or single fiber of a side emitting fiber or guide to internally activate a promoter or catalyst on the exterior of the fiber or guide to thereby dissociate target molecules passing by or along the fiber's or guide's surface by a Precise Energy Separation (“PES”) method. A number of different designs can be used, for example, in a mesh, louver system, or box. The method maximizes the interaction between the target molecules and the surface of the side emitting-internally activated distribution network. In a preferred embodiment, u-shaped fiber optics containing catalyst are positioned within tube through which the turbid liquid or air is passed, so that maximum cleavage of targeted bonds is obtained.Type: ApplicationFiled: October 18, 2013Publication date: April 24, 2014Applicant: Fahs Stagemyer LLCInventor: Richard W. Fahs, II
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Publication number: 20130213899Abstract: A system has been developed to treat ballast water by selectively dissociating target molecules into component products compositionally distinct from the target molecule, wherein the bonds of the target molecule do not reform because the components are no longer reactive with each other. Dissociation is affected by treating the target molecule with light at a frequency and intensity, alone or in combination with a catalyst in an amount effective to selectively break bonds within the target molecule. Dissociation does not result in re-association into the target molecule by the reverse process, and does not produce component products which have a change in oxidation number or state incorporated oxygen or other additives because the process does not proceed via a typical reduction-oxidation mechanism.Type: ApplicationFiled: February 25, 2013Publication date: August 22, 2013Applicant: FAHS STAGEMYER LLCInventor: Fahs Stagemyer LLC
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Patent number: 8440154Abstract: A process has been developed to selectively dissociate target molecules into component products compositionally distinct from the target molecule, wherein the bonds of the target molecule do not reform because the components are no longer reactive with each other. Dissociation is affected by treating the target molecule with light at a frequency and intensity, alone or in combination with a catalyst in an amount effective to selectively break bonds within the target molecule. Dissociation does not result in re-association into the target molecule by the reverse process, and does not produce component products which have a change in oxidation number or state incorporated oxygen or other additives because the process does not proceed via a typical reduction-oxidation mechanism. Target molecules include ammonia for waste reclamation and treatment, PCB remediation, and targeted drug delivery.Type: GrantFiled: June 15, 2012Date of Patent: May 14, 2013Assignee: Fahs Stagemyer, LLcInventors: Richard W. Fahs, II, Matthew D. W. Fahs
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Patent number: 8202500Abstract: A process has been developed to selectively dissociate target molecules into component products compositionally distinct from the target molecule, wherein the bonds of the target molecule do not reform because the components are no longer reactive with each other. Dissociation is affected by treating the target molecule with light at a frequency and intensity, alone or in combination with a catalyst in an amount effective to selectively break bonds within the target molecule. Dissociation does not result in re-association into the target molecule by the reverse process, and does not produce component products which have a change in oxidation number or state incorporated oxygen or other additives because the process does not proceed via a typical reduction-oxidation mechanism. Target molecules include ammonia for waste reclamation and treatment, PCB remediation, and targeted drug delivery.Type: GrantFiled: August 23, 2010Date of Patent: June 19, 2012Assignee: Fahs Stagemyer, LLCInventors: Richard W. Fahs, II, Matthew D. W. Fahs