The present application provides a waste disposal method that is applied to a composter including a storage cavity. The waste disposal method includes performing a first composting operation in response that first kitchen waste has been added into the storage cavity. Once the first composting operation is stopped, an internal environment of the storage cavity is adjusted to meet a composting condition of the first kitchen waste by performing an environment adjustment operation on the storage cavity according to a first time interval.

The present application provides a waste disposal method that is applied to a composter including a storage cavity. The waste disposal method includes performing a first composting operation in response that first kitchen waste has been added into the storage cavity. Once the first composting operation is stopped, an internal environment of the storage cavity is adjusted to meet a composting condition of the first kitchen waste by performing an environment adjustment operation on the storage cavity according to a first time interval.

A composting machine includes a fermentation reservoir for holding anaerobic waste and a microbe dispensing device positioned at least partially above the fermentation reservoir. The microbe dispensing device includes a microbe reservoir for receiving a microbe product and a dispensing mechanism for selectively depositing the microbe product into the fermentation reservoir to facilitate a fermentation process of the anaerobic waste.

A composting machine includes a fermentation reservoir for holding anaerobic waste and a microbe dispensing device positioned at least partially above the fermentation reservoir. The microbe dispensing device includes a microbe reservoir for receiving a microbe product and a dispensing mechanism for selectively depositing the microbe product into the fermentation reservoir to facilitate a fermentation process of the anaerobic waste.

This invention discloses and claims a system comprising greenhouses or dehydrators for receiving biosolids; a pasteurization building to receive the biosolids from the greenhouse, at least one pasteurization system comprising heat up belts, a burner fan to heat the biosolids, a pasteurization belt to convey the biosolids through a pasteurization chamber; holding tanks to receive the biosolids and enhancement storage to hold enhancements, a scale and a blender to blend the biosolids with the one or more enhancements, a pellet mill to receive a blended fertilizer, the pellet mill comprising a die to form the blended fertilizer into a pellet and a knife to cut the pellet to a desired length, wherein the pellet mill further comprises a temperature-controlled die operable to control the temperature of the blended fertilizer to promote the formation of the pellets.

This invention discloses and claims a system comprising greenhouses or dehydrators for receiving biosolids; a pasteurization building to receive the biosolids from the greenhouse, at least one pasteurization system comprising heat up belts, a burner fan to heat the biosolids, a pasteurization belt to convey the biosolids through a pasteurization chamber; holding tanks to receive the biosolids and enhancement storage to hold enhancements, a scale and a blender to blend the biosolids with the one or more enhancements, a pellet mill to receive a blended fertilizer, the pellet mill comprising a die to form the blended fertilizer into a pellet and a knife to cut the pellet to a desired length, wherein the pellet mill further comprises a temperature-controlled die operable to control the temperature of the blended fertilizer to promote the formation of the pellets.

A method for reducing particles from biosolids, comprising a storage tank for holding biosolids and an inlet pipe. The inlet pipe delivers biosolids from the storage tank to a screener and then to a percent solids meter. The percent solids meter measures the solid content in the biosolids and sends a signal to an electronic solenoid valve to control water content of the biosolids introduced to the system. A first venturi hydrodynamic cavitation to create vacuum bubbles in the biosolids. A mechanical hydrodynamic cavitation device operably connected to first venturi hydrodynamic cavitation, wherein the mechanical hydrodynamic cavitation device creates vacuum bubbles in the biosolids.

A method for reducing particles from biosolids, comprising a storage tank for holding biosolids and an inlet pipe. The inlet pipe delivers biosolids from the storage tank to a screener and then to a percent solids meter. The percent solids meter measures the solid content in the biosolids and sends a signal to an electronic solenoid valve to control water content of the biosolids introduced to the system. A first venturi hydrodynamic cavitation to create vacuum bubbles in the biosolids. A mechanical hydrodynamic cavitation device operably connected to first venturi hydrodynamic cavitation, wherein the mechanical hydrodynamic cavitation device creates vacuum bubbles in the biosolids.

A method for reducing particles from biosolids, comprising a storage tank for holding biosolids and an inlet pipe. The inlet pipe delivers biosolids from the storage tank to a screener and then to a percent solids meter. The percent solids meter measures the solid content in the biosolids and sends a signal to an electronic solenoid valve to control water content of the biosolids introduced to the system. A first venturi hydrodynamic cavitation to create vacuum bubbles in the biosolids. A mechanical hydrodynamic cavitation device operably connected to first venturi hydrodynamic cavitation, wherein the mechanical hydrodynamic cavitation device creates vacuum bubbles in the biosolids.

A method for reducing particles from biosolids, comprising a storage tank for holding biosolids and an inlet pipe. The inlet pipe delivers biosolids from the storage tank to a screener and then to a percent solids meter. The percent solids meter measures the solid content in the biosolids and sends a signal to an electronic solenoid valve to control water content of the biosolids introduced to the system. A first venturi hydrodynamic cavitation to create vacuum bubbles in the biosolids. A mechanical hydrodynamic cavitation device operably connected to first venturi hydrodynamic cavitation, wherein the mechanical hydrodynamic cavitation device creates vacuum bubbles in the biosolids.