The invention provides for methods, devices, and systems for pyrolyzing biomass. A pyrolysis unit can be used for the pyrolysis of biomass to form gas, liquid, and solid products. The biomass materials can be selected such that an enhanced biochar is formed after pyrolysis. The biomass can be pyrolyzed under specified conditions such that a selected biochar core is formed. The pyrolysis process can form a stable biochar core that is inert and/or resistant to degradation. The biochar or biochar core can be functionalized to form a functionalized biochar or functionalized biochar core. Functionalization can include post-pyrolysis treatments such as supplementation with microbes or physical transformations including annealing and/or activation.

The invention provides for methods, devices, and systems for pyrolyzing biomass. A pyrolysis unit can be used for the pyrolysis of biomass to form gas, liquid, and solid products. The biomass materials can be selected such that an enhanced biochar is formed after pyrolysis. The biomass can be pyrolyzed under specified conditions such that a selected biochar core is formed. The pyrolysis process can form a stable biochar core that is inert and/or resistant to degradation. The biochar or biochar core can be functionalized to form a functionalized biochar or functionalized biochar core. Functionalization can include post-pyrolysis treatments such as supplementation with microbes or physical transformations including annealing and/or activation.

The present invention relates to a process for the production of a phosphate containing fertilizer product, comprising the steps of providing a phosphate containing precipitate from a wastewater treatment process; separating water from the precipitate to provide a dewatered slurry cake; and optionally admixing a compound selected from nitrogen, potassium and additional phosphorous containing compounds. The present invention further relates to a fertilizer and uses.

The problem of the present invention is to provide a magnesium hydroxide [Mg(OH).sub.2] fertilizer to supply magnesium to plants without costs and time and to cultivate plants safely and economically using the magnesium hydroxide [Mg(OH).sub.2] fertilizer. The above problem can be solved by effectively using laundry wastewater containing magnesium hydroxide [Mg(OH).sub.2] after washing the laundry using magnesium material containing water and metal magnesium (Mg) as a main component.

The problem of the present invention is to provide a magnesium hydroxide [Mg(OH).sub.2] fertilizer to supply magnesium to plants without costs and time and to cultivate plants safely and economically using the magnesium hydroxide [Mg(OH).sub.2] fertilizer. The above problem can be solved by effectively using laundry wastewater containing magnesium hydroxide [Mg(OH).sub.2] after washing the laundry using magnesium material containing water and metal magnesium (Mg) as a main component.

A portable renewable energy microgeneration system is disclosed. The system comprises one or more holding tanks that are configured to perform anaerobic digestion on waste in a multi-phase process using bacteria and a controller configured to automatically control the multi-phase process and to re-use the bacteria. The controller re-uses the bacteria by removing at least a portion of the liquid from the waste after anaerobic digestion is performed on the waste and using the at least a portion of the liquid to wet other waste and repeat the multi-phase process.

A portable renewable energy microgeneration system is disclosed. The system comprises one or more holding tanks that are configured to perform anaerobic digestion on waste in a multi-phase process using bacteria and a controller configured to automatically control the multi-phase process and to re-use the bacteria. The controller re-uses the bacteria by removing at least a portion of the liquid from the waste after anaerobic digestion is performed on the waste and using the at least a portion of the liquid to wet other waste and repeat the multi-phase process.

A system and method for preparing a microbial supplement, and applying the supplement to plants, trees and other items to promote their growth. The supplement comprises seawater, including microbes that naturally exist in seawater. Seawater is harvested containing microbes in an inactive or dormant state. The seawater undergoes a filtration, mineralization and oxygenation process to reduce sodium chloride levels, to increase the levels of desirable minerals in the seawater and to oxygenate the seawater to keep the microbes alive, though in a dormant or inactive state. The microbes are maintained in an inactive or dormant state through the preparation process, but become active when the supplement is applied to plants or trees, thereby promoting agricultural growth.

A system and method for preparing a microbial supplement, and applying the supplement to plants, trees and other items to promote their growth. The supplement comprises seawater, including microbes that naturally exist in seawater. Seawater is harvested containing microbes in an inactive or dormant state. The seawater undergoes a filtration, mineralization and oxygenation process to reduce sodium chloride levels, to increase the levels of desirable minerals in the seawater and to oxygenate the seawater to keep the microbes alive, though in a dormant or inactive state. The microbes are maintained in an inactive or dormant state through the preparation process, but become active when the supplement is applied to plants or trees, thereby promoting agricultural growth.

Systems and methods for employment in a Zero Waste (ZW) treatment system are disclosed. The ZW treatment system includes a ZW process employing the following individual processes: a separation and extraction process, a blend-heat process, a hydrolysis and acidification process, first-in, first-out (FIFO) anaerobic digestion process, an aerobic boost-blend process, and smart delivery process. A separation and extraction system, a blend-heat system, hydrolysis and acidification system, and a FIFO system performing the ZW treatment process may include a variety of tanks, where each tank may be placed in an enclosure comprising a modular container which, in turn, comprises a modular container system designed for mobility and transportable to remote sites as part of the smart delivery process.