A method of determining the volume of organic material in a composting device includes rotating a mixing paddle in a composting bin that stores the organic material; monitoring the torque from a motor that rotates the mixing paddle as the mixing paddle rotates; and determining the height of the organic material in the composting bin based on the motor torque and the angular displacement of the mixing paddle. The resulting height can be used to determine the volume of the organic material.

A renewable energy microgeneration apparatus is disclosed that includes a mixing tank that mixes waste with a liquid, a buffer tank that receives and pre-warms the mixed waste, a pasteurization tank that pasteurizes on the pre-warmed mixed waste, a digestion tank that performs anaerobic digestion on the pasteurized waste, a de-watering device that separates liquid digestate and removes salt from the liquid, sensors that measure salinity and biogas quality, and a controller. The controller causes the transfer of digestate from the digestion tank to the pasteurization tank to the dewatering device, causes the de-watering device to separate the liquid and remove the salt from the liquid, monitors the salinity of the liquid and the quality of biogas using the sensors, and causes the mixing of the liquid with the waste and adjusts the feed rate of the waste to reduce the salinity of the waste and increase methane production.

The present invention relates to organic nitrogen fertilizers and methods for producing organic nitrogen fertilizers, including retrieving high concentration organic ammonia from discarded organic material.

The present invention relates to organic nitrogen fertilizers and methods for producing organic nitrogen fertilizers, including retrieving high concentration organic ammonia from discarded organic material.

The present invention relates to organic nitrogen fertilizers and methods for producing organic nitrogen fertilizers, including retrieving high concentration organic ammonia from discarded organic material.

A renewable energy microgeneration apparatus is disclosed that includes a mixing tank that mixes waste with a liquid, a buffer tank that receives and pre-warms the mixed waste, a pasteurization tank that pasteurizes on the pre-warmed mixed waste, a digestion tank that performs anaerobic digestion on the pasteurized waste, a de-watering device that separates liquid digestate and removes salt from the liquid, sensors that measure salinity and biogas quality, and a controller. The controller causes the transfer of digestate from the digestion tank to the pasteurization tank to the dewatering device, causes the de-watering device to separate the liquid and remove the salt from the liquid, monitors the salinity of the liquid and the quality of biogas using the sensors, and causes the mixing of the liquid with the waste and adjusts the feed rate of the waste to reduce the salinity of the waste and increase methane production.

The current application relates to a liquid fertilizer composition for application to plants and soils, comprising an autothermal thermophilic aerobic bioreaction product from a liquid fraction of poultry manure and further to a method of improving health and productivity of a plant or crop using said composition and to a method of conditioning soil using said composition.

A thermophilic enzymatic biosynthesis (TEBS) device (50) produces outputs of newly synthesized substances, stabilized matter and fully recovered organic material, wherein the preferred device is a dry closet employing multistage treatment of organic solid, liquid and gaseous wastes. Said contemplated device comprises a multiphase thermophilic environment chamber (MTEC) (1) having a mixing zone (4), a cultivation zone (12), a pasteurization zone (24) and a germination zone (7) which utilizes a multiphase germination (62). The device comprises a thermodynamic pathway (29) and a functional respiration (64) which is directed toward an ammine reaction chamber (ARC) (3), which includes an oxidation surface (47) having reactivity with ammonia, producing a metal ammine complex. The device further comprises a subterranean uptake chamber (SUC) (2) which includes a plant growth medium (44) where gases received from the ARC (3) disperse to an uptake root structure (46), thereby reducing carbon dioxide emissions.

This invention is a method for the processing of organic materials or organic wastes in a cost-effective and environmentally sound manner. The invention works both in the anaerobic or aerobic state. Processing organic material is accomplished by forcing the flow of gas through a pile of material, containing some organic matter, with liquids and gravity. The movement of gas and liquids through the pile results in very large increases in microorganism populations, accelerated evolution of the microorganisms, and corresponding increases in the processing provided organic materials.

A system and method for capturing CO2 from air includes exposing the air to a source of water such that CO2 in the water is below equilibrium with CO2 in the air. The water may be enriched with hydroxides. In a preferred embodiment, the CO2 may be captured along with ammonia that is released from decomposing biomass using an apparatus including a first chamber receiving the water and a second chamber receiving the decomposing biomass. The first and second chambers are connected to allow transmission of air between the chambers while collectively defining an enclosed space from which air cannot escape. As the biomass decomposes, the enclosed air is enriched with CO2 and ammonia such that the CO2 in the water is below equilibrium with CO2 in the air so the water absorbs some of the CO2 in the air within the enclosed space.