A spiral growing system is configured to be housed in a vertically elongated silo growth chamber to grow an agricultural crop. The spiral growing system broadly includes a spiral growing assembly and a movable crop support with a continuous track and optional feeding system. The track extends continuously along the assembly length of the spiral growing assembly and presents a generally downward spiral path that defines a path axis, with the track configured to direct the agricultural crop along the spiral path to thereby direct the agricultural crop through the growing space along the spiral path.

A spiral growing system is configured to be housed in a vertically elongated silo growth chamber to grow an agricultural crop. The spiral growing system broadly includes a spiral growing assembly and a movable crop support with a continuous track and optional feeding system. The track extends continuously along the assembly length of the spiral growing assembly and presents a generally downward spiral path that defines a path axis, with the track configured to direct the agricultural crop along the spiral path to thereby direct the agricultural crop through the growing space along the spiral path.

A method of generating multifunctional mycelium products (thread, foam, films, gels and liquids) derived from biodegraded waste and fungi includes inoculating a carbon-containing substrate with fungi; growing the fungi to form a mature mycelium; separating the mycelium from the carbon-containing substrate; and drying the mature mycelium. The mycelium is either injected into a mold and expanded, fermented to produce a liquid, or blended with water and gelling agents to form a hydrogel. The products sequester carbon and inherently combat pathogens, notably MRSA. Further augmented with synthetic enzyme substrates, the products offer bacterial detection. A standout feature is their capacity to hold and release therapeutic agents, diversifying their use from sustainable textiles to skincare, wound healing, and precise drug delivery.

Techniques for generating high-yield fungi production are disclosed. In one particular embodiment, the techniques may be realized as a system for generating high-yield fungi production, the system comprising at least one modular container and a growing system housed within the modular container. The growing system may include a substrate preparation system configured to accept substrate and prepare substrate for pasteurization, a pasteurization system configured to pasteurize prepared substrate received from the substrate preparation system, a draining, cooling, and packing system configured to cool and drain pasteurized prepared substrate from the pasteurization system and to pack pasteurized and cooled substrate into at least one growing container, an inoculation system configured to inoculate the pasteurized and cooled substrate, and a plurality of vertical racks coupled to a ceiling of the modular container and configured to hold the at least one growing container.

Process for growing mycelium sheets. First, a substrate mixture is prepared in a mixer. Then the substrate mixture is applied as substrate layers on shelves of a rack in a cultivation room. The cultivation room is then closed and subsequently the substrate is pasteurized by injecting a pasteurizing medium, such as steam, into the closed cultivation room. In a next step, the substrate mixture is cooled and subsequently inoculated. During a growing step mycelium is allowed to grow on the inoculated substrate mixture. In a next harvesting step, the mycelium is separated from the substrate.

Process for growing mycelium sheets. First, a substrate mixture is prepared in a mixer. Then the substrate mixture is applied as substrate layers on shelves of a rack in a cultivation room. The cultivation room is then closed and subsequently the substrate is pasteurized by injecting a pasteurizing medium, such as steam, into the closed cultivation room. In a next step, the substrate mixture is cooled and subsequently inoculated. During a growing step mycelium is allowed to grow on the inoculated substrate mixture. In a next harvesting step, the mycelium is separated from the substrate.

A method using a system 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 method using a system 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 mushroom grow assembly has a top cover, a base assembly, a post and a transparent cover. The top cover includes a concave wall with a peripheral edge, a top opening, through openings and an upper receiving housing. The base assembly includes a lateral wall, a bottom wall and lower receiving housing. The post has a bottom wall that is mounted to the lower receiving housing and a top edge that is introduced inside the upper receiving housing. The transparent cover is mounted to the edges of base assembly and the top cover, surrounding said post. The top cover further includes a light assembly and a water chamber disposed inside said upper receiving housing. The post is filled with mushroom inoculated substrate. The base assembly, in an upside down disposition, can replace the top cover to allow at least one additional mushroom grow assembly be stacked below.

A mushroom grow assembly has a top cover, a base assembly, a post and a transparent cover. The top cover includes a concave wall with a peripheral edge, a top opening, through openings and an upper receiving housing. The base assembly includes a lateral wall, a bottom wall and lower receiving housing. The post has a bottom wall that is mounted to the lower receiving housing and a top edge that is introduced inside the upper receiving housing. The transparent cover is mounted to the edges of base assembly and the top cover, surrounding said post. The top cover further includes a light assembly and a water chamber disposed inside said upper receiving housing. The post is filled with mushroom inoculated substrate. The base assembly, in an upside down disposition, can replace the top cover to allow at least one additional mushroom grow assembly be stacked below.