A system for growing fungi, the system comprising a nutritive vehicle, a porous material, an administrable space, fungal tissue comprising fungal hyphae having a growth pattern, the fungal tissue connecting said nutritive vehicle to said porous material to said administrable space, wherein the fungal tissue within said space defines at least one successive fungal material layer; and a chemically or physically altered separated portion of fungal material, the separated portion separated from said fungal tissue.

A system for growing fungi, the system comprising a nutritive vehicle, a porous material, an administrable space, fungal tissue comprising fungal hyphae having a growth pattern, the fungal tissue connecting said nutritive vehicle to said porous material to said administrable space, wherein the fungal tissue within said space defines at least one successive fungal material layer; and a chemically or physically altered separated portion of fungal material, the separated portion separated from said fungal tissue.

A container assembly for a mushroom growing system includes a tray and a plurality of containers. The tray includes a plurality of tray locating structures attached relative to one another and spaced horizontally to cooperatively define a supporting tray surface of the tray. Each container is biodegradable and is configured to be removably supported by the tray. The container includes a cup and a container cover that present an enclosed chamber to receive a colonized substrate for growing mushrooms.

A container assembly for a mushroom growing system includes a tray and a plurality of containers. The tray includes a plurality of tray locating structures attached relative to one another and spaced horizontally to cooperatively define a supporting tray surface of the tray. Each container is biodegradable and is configured to be removably supported by the tray. The container includes a cup and a container cover that present an enclosed chamber to receive a colonized substrate for growing mushrooms.

The invention relates to a cultivation arrangement. A first and a second rack are arranged adjacent and aligned with each other, providing a working space therebetween. Each rack comprises support structures arranged at support heights for supporting cultivation packages at a plurality of heights. The support heights are aligned with each other. The support structures comprises one or more guiding members and the arrangement comprises moving means arranged for moving packages from the first to the second rack or back, via the working space. Cultivation packages can be supported such that at most a single package is supported at each of the aligned support heights. This enables the packages to be alternatingly supported in either the first or the second rack across the support heights. The arrangement further includes an operator platform contiguous to the working space which is moveable in a vertical direction to enable working at different heights.

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.

An automated mushroom harvesting system for mounting to a vertical mushroom rack comprises a robot having a frame mounted to a vertical carriage assembly. A SCARA arm is slidably mounted to the vertical carriage assembly by a vertical stage, operable to move the SCARA arm along a vertical mast. The SCARA arm moves the end effector in a horizontal plane for harvesting mushrooms, above the surface of the mushroom bed and into and out of the confines of the mushroom rack, and the vertical stage moves the SCARA arm in a vertical direction so as to access the mushrooms in a bed and to access mushroom beds on different levels of the vertical mushroom rack. An end effector having a helically reinforced neck and a graduated elasticity modulus, with a lower elasticity modulus in the neck and a higher elasticity in the cup, is also provided.

An automated mushroom harvesting system for mounting to a vertical mushroom rack comprises a robot having a frame mounted to a vertical carriage assembly. A SCARA arm is slidably mounted to the vertical carriage assembly by a vertical stage, operable to move the SCARA arm along a vertical mast. The SCARA arm moves the end effector in a horizontal plane for harvesting mushrooms, above the surface of the mushroom bed and into and out of the confines of the mushroom rack, and the vertical stage moves the SCARA arm in a vertical direction so as to access the mushrooms in a bed and to access mushroom beds on different levels of the vertical mushroom rack. An end effector having a helically reinforced neck and a graduated elasticity modulus, with a lower elasticity modulus in the neck and a higher elasticity in the cup, is also provided.

A mycelium growth bed for growing a solid substrate-bound mycelium through which the mycelium composite is easily and readily removed. This is achieved through the use of a perforation layer embedded between the mycelium substrate and the mycelium composite so as to create a uniform structural weakness and thereby enhancing harvesting abilities of the ex-substrate mycelium via a greatly reduced and uniform tear strength. The perforation layer, through which the mycelium grows, allows for the gated and controlled extrusion of a matrix of colonial cells that may be easily and uniformly delaminated from the underlying mycelium substrate.

A mycelium growth bed for growing a solid substrate-bound mycelium through which the mycelium composite is easily and readily removed. This is achieved through the use of a perforation layer embedded between the mycelium substrate and the mycelium composite so as to create a uniform structural weakness and thereby enhancing harvesting abilities of the ex-substrate mycelium via a greatly reduced and uniform tear strength. The perforation layer, through which the mycelium grows, allows for the gated and controlled extrusion of a matrix of colonial cells that may be easily and uniformly delaminated from the underlying mycelium substrate.