Systems and methods of generating water for growing or vitally supporting plants, fungi, and/or aquatic animals are provided herein. The systems include a water generating unit that utilizes process fluid produced by plant transpiration or fungus respiration to generate water. Nutrients may be added to the water through hydroponic and aquaponic systems, then provided back to the plants in a closed loop. The systems may be monitored, optimized, and controlled remotely.

Apparatus and processes to grow a biomaterial made of aerial mycelium by sensing and controlling airborne mist concentration, regardless of relative humidity. A growth matrix comprising a growth medium and a fungus, is grown under controlled environmental conditions to produce a mycelium product. To control growth conditions precisely and efficiently, airborne mist is electronically detected using one or more sensors, configured to measure airborne mist concentration visually, optically, chemically, electromagnetically, or by laser, ultrasonically, with radar, or other means. Electronic detection of airborne mist using one or more sensors generates a signal that is transmitted to a processor that can either maintain, increase, or decrease airborne mist concentration in a growth environment. The present invention provides processes of growing mycelium that are repeatable and resource efficient, while providing high quality and quantity mycelium-based products.

A growing system is described where plants are grown in containers and the containers are stored in stacks. Above the stacks runs a grid network of tracks on which load handling devices run. The load handling devices take containers from the stacks and deposit then at alternative locations in the stacks or deposit them at stations where goods may be picked out. The containers may be provided with one or more of the following services: power, power control, heating, lighting, cooling, sensing means, data logging means, growing means, water and nutrients.

The subject invention relates to novel systems, materials and methods for aseptic production of fungi on a large scale. In particular, the subject invention provides systems, materials and methods for producing endomycorrhizal fungal propagules, including spores and hyphal mycelium, using a two-stratum system supplemented with plant hormones and other natural growth stimulators.

A lockable equipment rack for a backpack blower is presented. A lockable equipment rack includes adjustable components configured to storage of a variety of backpack blowers. The equipment rack can be installed in a variety of locations, for example a trailer, and securely store the backpack blower. The lockable equipment rack prevents theft of the backpack blower and tampering of its components.

A lockable equipment rack for a backpack blower is presented. A lockable equipment rack includes adjustable components configured to storage of a variety of backpack blowers. The equipment rack can be installed in a variety of locations, for example a trailer, and securely store the backpack blower. The lockable equipment rack prevents theft of the backpack blower and tampering of its components.

A system and method adapted for continuous growth and harvesting of fungal fruiting bodies. The system includes a growth chamber, one or more mycelium feed assemblies, a nutrient reservoir with liquid media, one or more environmental controls to control an environment within the growth chamber and of the liquid media within the nutrient reservoir. One or more mycelium feed assemblies are arranged within the growth chamber. Each of the one or more mycelium feed assemblies includes a nutrient supply member and a mycelium colony which grows around the nutrient supply member, that continuously supplies liquid media to the mycelium colony. The method includes starting one or more mycelium colonies on the nutrient supply member, establishing that a mature colony has formed, and then maintaining the mature mycelium colony by continuous delivery of liquid medium to the mycelium colony, thus allowing for contiguous generation and harvesting of fungal fruiting bodies.

A system and method adapted for continuous growth and harvesting of fungal fruiting bodies. The system includes a growth chamber, one or more mycelium feed assemblies, a nutrient reservoir with liquid media, one or more environmental controls to control an environment within the growth chamber and of the liquid media within the nutrient reservoir. One or more mycelium feed assemblies are arranged within the growth chamber. Each of the one or more mycelium feed assemblies includes a nutrient supply member and a mycelium colony which grows around the nutrient supply member, that continuously supplies liquid media to the mycelium colony. The method includes starting one or more mycelium colonies on the nutrient supply member, establishing that a mature colony has formed, and then maintaining the mature mycelium colony by continuous delivery of liquid medium to the mycelium colony, thus allowing for contiguous generation and harvesting of fungal fruiting bodies.

The present invention relates to a device for discharging mushrooms from a conveyor, comprising a mushroom conveyor, in particular a conveyor belt and/or an endless conveyor, for conveying the mushrooms in a direction of conveyance; wherein the mushroom conveyor has a surface for carrying the mushrooms; and the mushroom conveyor being guided along a trajectory from a charging location such as a picking location to a discharging location, such as a filling station for mushroom containers, as well as a twister, located at the discharging location, for at least locally twisting a plane in which the surface of the mushroom conveyor lies.

An array system of passive solar aquaponic and mushroom production structures, each having a glazing on a sun facing side to maximize winter sunlight; a plant growing area; a mushroom growing area; a water wall thermal mass integrated and disposed between the plant and mushroom growing areas; a fish tank; a saltwater basin under the plant growing holding saltwater; a natural air ventilation system providing misted air to the mushroom growing area and receiving O2 from the plant growing provided to the mushroom growing area, and CO2 generated by the mushroom growing area provided to the plant growing area; and saltwater channels delivering saltwater to the saltwater basins from a saltwater source, and which is evaporated by solar heat generated by the plant growing areas in order to generate freshwater.