Patent application number | Description | Published |
20110056124 | Algal Coal and Process for Preparing Same - Algae-derived synthetic coal and filtrates. The invention described herein provides an algae-derived synthetic coal product and filtrates and process for preparing the same using an improved hydrothermal carbonization process. The synthetic coal product is similar to natural bituminous coal in terms of percent carbon content and energy equivalency while at the same time containing relatively low levels of sulfur and contaminant heavy metals. Unlike natural coal and other fossil fuels, because the carbon of the biomass is formed through photosynthesis, carbon dioxide formed during combustion is a “carbon neutral” event with little or no “new” carbon dioxide being added to the earth's atmosphere. The algae-derived filtrates contain useful constituents. | 03-10-2011 |
20110271588 | SYNTHETIC COAL AND METHODS OF PRODUCING SYNTHETIC COAL FROM FERMENTATION RESIDUE - Synthetic coal, methods of producing synthetic coal, produced from fermentation residue, such as the residue from ethanol production, by subjecting the fermentation residue to hydrothermal carbonization in an aqueous solution at a temperature and a pressure sufficient to form a synthetic coal solid and a liquid component. The solid synthetic coal component has a low ash content and may be used as a carbon source for energy production, such as for combustive thermal energy generation, or for gassification for the production of synthesis gas. | 11-10-2011 |
20130206571 | PROCESS FOR OBTAINING OILS, LIPIDS AND LIPID-DERIVED MATERIALS FROM LOW CELLULOSIC BIOMASS MATERIALS - The present invention concerns low energy requiring methods for processing low cellulosic biomass materials into oil, char and liquid components. One method comprises the steps of subjecting the biomass to hydrothermal carbonization under specified reaction conditions for producing a combined char and oil fraction as well as an aqueous fraction, separating the combined oil and char fraction from the aqueous fraction by filtration; separating the combined oil and char fraction into individual oil and char fractions using an organic solvent for forming an oil depleted char fraction and a liquid oil and solvent solution, and separating the liquid oil and solvent solution into individual oil and solvent fractions by distillation. | 08-15-2013 |
20140033777 | Methods of Producing Coal and Fertilizers from Fermentation Residues - The present invention concerns a process for producing synthetic coal and aqueous liquid plant fertilizing solution products from a fermentation residue such as is left over from the corn based process of producing ethanol. The synthetic coal has a high heat value commensurate with naturally occurring coals and is lower in ash and sulfur content and thus has value as a clean burning energy source. The aqueous fertilizer includes commercially useful amounts of phosphorous, potassium and nitrogen in solution. The process of the invention is also energy efficient in that the products produced thereby involve the use of substantially less energy as compared to the traditional methods of processing fermentation residues in the corn based ethanol production industry. | 02-06-2014 |
Patent application number | Description | Published |
20140323694 | MULTIPHASE POROUS FLOW REACTORS AND METHODS OF USING SAME - PFRs for running multiphasic processes are disclosed. The PFRs are single or multi-chamber devices having at least three types of regions (a liquid-contacting region, a gas-contacting region and a liquid-collection region), and a porous substrate providing fluid communication at least between the liquid-contacting and gas-contacting regions. Removal of liquid from the porous substrate, such as by collecting the liquid as it flows off the bottom of the porous substrate in the liquid-collection region or such as by evaporation of the liquid from the porous substrate in the evaporation region supports a continuous flow process. Methods of using the PFRs are also disclosed, for example methods of using the PFRs as photobioreactors for cultivating photosynthetic microorganisms, for producing fermentable sugars, for producing ethanol, for fermenting synthesis gas and producing single cell protein from natural gas. | 10-30-2014 |
20150183641 | HYDROTHERMAL CARBONIZATION OF SEWAGE WASTES - The present disclosure provides methods for hydrothermally treating sewage wastes to preferably obtain valuable products, including fatty acids, carbon-neutral combustible hydrochar fuels, heavy metal salts for recycling into industrially important metals, and phosphoric acid and derivatives thereof. Fatty acids can be chemically transformed into useful products such as soaps, cosmetics and liquid transportation fuels such as biodiesel and conventional gasoline, diesel and aviation fuels; hydrochars created in the process can be combusted and the energy created used to generate electricity; heavy metal salts can be chemically reduced to form industrially important metals for use as catalysts; and phosphoric acid and its derivatives have very important roles as fertilizers in agriculture. | 07-02-2015 |
20150184147 | STRUCTURED BIOLOGICAL MATERIALS AND RELATED PRODUCTS AND METHODS - The disclosure describes Structured Biological Materials (“SBM”) adapted for use in emulsion-less multiphasic processes. The SBM is a substratum-microbial matrix combination, wherein the microbial matrix houses one or more natural or genetically-engineered microorganisms capable of catalyzing or performing reactions that occur in multiphasic environments. When used in an emulsion-less system, the SBMs should be able to maintain separation of the bulk phases sufficient to maintain the emulsion-less nature of the system. The disclosure also provides methods of using the SBMs, for example in performance of multiphasic reactions, such as emulsion-less biphasic liquid/liquid reactions. This disclosure also provides multiphasic membrane reactors wherein an SBM functions as the membrane, such as emulsion-less biphasic reactors wherein an SBM functions as the biphasic membrane. | 07-02-2015 |