Parnas
Moshe Parnas, Mevaseret Tziyon IL
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20110281949 | METHODS AND COMPOSITIONS FOR TREATING NEURONAL DAMAGE AND MODULATING TRANSIENT RECEPTOR POTENTIAL CHANNELS - Use of alkyl phenol and monocyclic monoterpene-derived compounds in the treatment of neuronal damage and in inhibiting activity of TRPC and non-thermo-TRPM channels, and use of bicyclic monoterpene-derived compounds in activating TRPC and non-thermo-TRPM channels. | 11-17-2011 |
Richard Parnas, West Hartford, CT US
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20090208380 | SYSTEMS FOR ALKYL ESTER PRODUCTION - In one embodiment, an alkyl ester production system can comprise: a first transesterification reactor comprising a liquid biomass inlet located between a liquid glycerol outlet and a liquid alkyl ester outlet, a water wash vessel comprising an alkyl ester inlet, a water inlet located near a top of the water wash vessel, and a washed alkyl ester outlet located near the top of the water wash vessel, wherein the alkyl ester inlet is located near a bottom of the water wash vessel, and a drier comprising a washed alkyl ester inlet located near a top of the drier, and a gas inlet and a dried alkyl ester outlet located near the bottom of the drier. The first transesterification reactor can be configured for laminar flow and for liquid reactants and products. The alkyl ester inlet can be in fluid communication with the washed alkyl ester outlet. | 08-20-2009 |
20120142952 | SYSTEMS FOR ALKYL ESTER PRODUCTION - In one embodiment, a method for the production of alkyl esters comprises: introducing liquid biomass and an alcohol to a first transesterification reactor at a point in a lower 25% of the reactor; reacting the liquid biomass and the alcohol to form a liquid glycerol and a liquid alkyl ester, wherein greater than or equal to about 75 mass % of the liquid glycerol moves towards a bottom of the first transesterification reactor; removing a liquid alkyl ester stream from the first transesterification reactor; and removing the liquid glycerol from the first transesterification reactor. The liquid biomass and the alcohol form a combined liquid stream that flows through the first transesterification reactor in a laminar flow. | 06-07-2012 |
Richard Parnas, Ashford, CT US
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20140054816 | Process for Particleboard Manufacture - Improved particleboard and methods for fabricating improved particleboard (e.g., natural fiber/material-based particleboard) are disclosed. More particularly, the present disclosure provides systems/methods for fabricating particleboard (e.g., formaldehyde-free particleboard) utilizing natural fibers/materials (e.g., lignocellulosic materials), wherein the particleboard has improved performance characteristics and/or mechanical properties. Methods for fabricating fiber-reinforced biocomposites (e.g., natural fiber-reinforced wheat gluten biocomposites) are disclosed. For example, systems/methods for fabricating particleboard from lignocellulosic materials (e.g., coconut materials), along with a binder material (e.g., wheat gluten), are provided. In general, the fiber or lignocellulosic material is treated with sodium hydroxide and/or a silane coupling agent as an adhesion promoter to enhance interfacial adhesion between the fiber and the binder. For example, (3-triethoxysilylpropyl)-t-butylcarbamate (MISO) (a masked isocyanate functional silane) was utilized to improve interfacial adhesion between the binder and the natural fibers. | 02-27-2014 |
20150217483 | Process for Particleboard Manufacture - Improved particleboard and methods for fabricating improved particleboard (e.g., natural fiber/material-based particleboard) are disclosed. More particularly, the present disclosure provides systems/methods for fabricating particleboard (e.g., formaldehyde-free particleboard) utilizing natural fibers/materials (e.g., lignocellulosic materials), wherein the particleboard has improved performance characteristics and/or mechanical properties. Methods for fabricating fiber-reinforced biocomposites (e.g., natural fiber-reinforced wheat gluten biocomposites) are disclosed. For example, systems/methods for fabricating particleboard from lignocellulosic materials (e.g., coconut materials), along with a binder material (e.g., wheat gluten), are provided. In general, the fiber or lignocellulosic material is treated with sodium hydroxide and/or a silane coupling agent as an adhesion promoter to enhance interfacial adhesion between the fiber and the binder. For example, (3-triethoxysilylpropyl)-t-butylcarbamate (MISO) (a masked isocyanate functional silane) was utilized to improve interfacial adhesion between the binder and the natural fibers. | 08-06-2015 |
Richard Parnas, Storrs, CT US
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20150291889 | PROCESS FOR CONVERTING FATS, OILS AND GREASES INTO FUELS - A method for producing a light oil fraction from plant-based and/or animal-based fats, oils or greases is disclosed. The method comprises introducing a feedstock including free fatty acids into a processing system. The system is heated at a controlled rate to a specified temperature, both of which are selected to produce a light oil fraction with a reduced fatty acid content. The system is permitted to reflux for a predetermined time, during which more of the light oil fraction is produced. The light oil fraction is separated from the remainder of the feedstock and contains less than 10% free fatty acids. | 10-15-2015 |
Richard S. Parnas, Winchester, MA US
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20090312175 | Increased Activity of Catalyst Using Inorganic Acids - The present disclosure provides for improved electrochemical devices (e.g., fuel cells, metal air batteries, ultra capacitors, etc.) and components therefore. More particularly, the present disclosure provides for improved systems and methods for producing materials, membranes, electrode assemblies (e.g., membrane electrode assemblies) and electrochemical devices employing the membranes and/or electrode assemblies. The present disclosure provides for improved systems and methods for producing high activity materials, membranes and/or electrode assemblies (e.g., MEAs) for use in electrochemical devices, wherein the high activity membranes and/or electrode assemblies include at least one inorganic acid. In exemplary embodiments, the present disclosure provides for improved systems and methods for producing high activity membranes and/or electrode assemblies (e.g., MEAs) for use in electrochemical devices, wherein the high activity membranes and/or electrode assemblies include at least one inorganic acid in the catalyst layer and/or in the cathode. | 12-17-2009 |
Richard S. Parnas, West Hartford, CT US
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20090247785 | METHODS AND SYSTEMS FOR PRETREATMENT OF AN OIL STREAM - In one embodiment, a method for pre-treating an oil comprises: introducing a oil, an alcohol, and an acid catalyst to a first continuous stirred tank reactor vessel, wherein the oil comprises free fatty acids; selectively reacting the oil and the alcohol to convert the free fatty acids to alkyl esters, wherein the reaction does not produce glycerol; removing a pre-treated oil stream from a lower portion of the first continuous stirred tank reactor, wherein the pre-treated oil stream comprises the alkyl esters; and recycling the alcohol and acid catalyst from an upper portion of the first continuous stirred tank reactor. | 10-01-2009 |
Richard S. Parnas, Ashford, CT US
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20110042315 | PERVAPORATION COMPOSITE MEMBRANE FOR AQUEOUS SOLUTION SEPARATION AND METHODS FOR USING THE SAME - In one embodiment, a membrane comprises: a nonporous, hydrophobic selective layer configured to be on a feed solution side of the membrane and polyethylene layer configured to be on a permeate side of the membrane, wherein the membrane is configured to selectively separate an organic component from an aqueous solution. In some embodiments, the method for separating an organic component from an aqueous stream can comprise: contacting a nonporous, hydrophobic selective layer of a membrane with the aqueous stream comprising the organic component, creating a vacuum on the side of the membrane comprising the support layer, permeating the organic component through the membrane into an exit chamber, and removing the organic component permeate from the exit chamber. | 02-24-2011 |