A process is disclosed for creating biologically active soil or horticulture media for growing plants, wherein a fibrous carbon source such as coconut coir in a predetermined particulate form is mixed with fertilizers and other biological nutrients, inoculated with a biologically active substance such as worm castings and then aged or cured in an oxygen rich aerobic process. After which additional nutrients can be added to tailor the aged media for a specific sue. Various apparatus with which to conduct the aging process are also described. In a variation of the process used soil or horticulture media is recharged by first composting at a high temperature to remove harmful and unwanted items, its contents are evaluated, nutrients are added, and it is then aged in an aerobic process.

A composting facility includes: a floor for receiving compostable material thereon, wherein the floor is constructed above-grade; a dovetail extending from the floor to allow ingress of a vehicle from a grade level to the floor; one or more channels defined within the floor and extending through the dovetail; a covering extending over the one or more channels to maintain the compostable material away from the channel, the covering defining at least one aperture extending from above the covering into the one or more channels for allowing flowthrough of gases; and an air source for providing air through the channels to provide cooling characteristics to the compostable material or oxygen to aid an aerobic process associated with composting. In operation, liquids draining from the composting material pass through the at least one aperture into the channel and out through a portion of the channel extending through the dovetail.

An Internet of Things (IoT) BIoTower for recycling food wastes into nutrients and for growing organic plants is disclosed which includes a food waste disposable tower for receiving food wastes; a multi-leveled carousels connected to the food waste disposable tower, each containing soils infested with earthworms; and an Internet of Things (IoT) irrigation system designed to provide sustainability to the soils and the organic plants.

A controller for a compost system comprises a plurality of control outputs in communication with a plurality of compost devices. The control outputs are configured to identify an error condition of at least one of the plurality of compost devices. The controller is configured to control a first compost device configured to control a first environmental condition and control a second compost device configured to control a second environmental condition of a compost chamber. The controller is further configured to deactivate the first compost device in response to an error condition during a compost cycle. The controller controls the second compost device in response to the first compost device being deactivated preserving the compost cycle by compensating for the error condition in the first compost device.

An apparatus as a countertop composter includes a container, a frame, a lid with holes that can be adjustably opened and closed. The container has a bottom wall, a side wall, an open top and a top edge defined by the side wall. The frame is configured to be coupled to and support the container. The container may be made of a resilient material. When the container is inverted, a force is applied onto the bottom of the container to remove the organic waste inside the container.

Biomass feedstocks (e.g., plant biomass, animal biomass, and municipal waste biomass) are processed to produce useful products, such as fuels. For example, systems are described that can convert feedstock materials to a sugar solution, which can then be fermented to produce ethanol. Biomass feedstock is dispersed in a liquid medium and then saccharified.

The present application relates to systems and methods for processing organic material. The methods may include extraction of biochemical nutrients from organic material, such as food scraps. The method can include comminuting the organic material to form a slurry from components comprising liquid and organic material; combining the slurry with microorganisms, such as a yeast, under aerobic conditions to form a mixture of the slurry and yeast; aerating the mixture; and forming a biomass and a nutrient-rich broth, in which the biochemical nutrients are stabilized and anabolized. The systems may, in some embodiments, be configured to perform the methods of processing organic materials.

The disclosure relates to a composting device including a housing defining an interior with an access opening providing access to the interior, a composter bin located within the interior and in communication with the access opening, and a cover slidably mounted to the housing and slidable along a sliding path between opened and closed conditions to selectively open and close the access opening. An angled seal assembly is provided on the cover and housing. Both a sealing surface and a seal are angled relative to a sliding path such that the space between the seal and the sealing surface decreases as the cover is slid from the opened to the closed condition.

Provided is an expandable, modular tower planter having an internal vertical composting capability, and a method of assembling and using the same. Provided in various example embodiments is a modular composting garden container system comprising a base and a plurality of stackable rings forming a tower upon the base, including an optional base ring specially sized, shaped, and positioned to connect the tower to the base. A plurality of perforated, stackable tube sections are provided that are removably assembled into a compost tube assembly of selectable height and mounted within the interior of the tower and above the base. A plurality of holding struts are sized, shaped, and positioned to removably connect the compost tube assembly with the tower and to securely locate the compost tube assembly relative to the tower. Means are provided for recovering nutrient-rich drainage and selective recovery of compost material for reintroduction into the system.

A method for vermicomposting includes providing an underground cell comprising a bottom, sidewalls and an open top, layering a base bedding layer at the bottom of the underground cell, layering a bottom organic waste layer on the base bedding layer, layering a stack of one (1) or more intermediate bedding layers and one (1) or more one or more intermediate organic waste layers, alternating between an intermediate bedding layer and an intermediate organic waste layer, on the bottom organic waste layer to partially form a compost heap, layering a top bedding layer on a top organic waste layer of the stack of the intermediate bedding layers and the intermediate organic waste layers to form the compost heap, watering the compost heap at a predetermined watering cycle, introducing worms to the compost heap, aerating the compost heap at a predetermined aeration cycle, and harvesting compost from the compost heap.