A device for harvesting mushrooms from a mushroom bed involves a robotic arm configured to interchangeably deploy one of a plurality of different suction grippers, each of the suction grippers having a suction cup having a size and shape profile appropriate for gripping a cap of a mushroom, the cap having a size and shape profile within a predetermined range. A vacuum source in fluid communication with the suction gripper supplies negative air pressure to the suction gripper for retaining a cap of the mushroom to be harvested in the suction cup. A control circuit in electronic communication with the suction gripper and the vacuum source is configured to automatically adjust the negative air pressure in the suction gripper in response to harvesting requirements during a mushroom harvesting process. A few standard mushroom shapes have been identified, which permits suction cup designs that maximize contact between the suction cups and the mushroom caps, which permits minimizing the strength of the vacuum needed to harvest the mushrooms.

A method for growing organically derived building materials in the form of a moldable substrate that can be engineered to serve a wide range of manufacturing and construction applications is presented. In particular, the embodiments consider a plurality of fungal molded shapes preferably grown from fungal inoculum and mechanically compressed at least once during the growing process as well as integration of structure support members to the fungal structure. The present invention provides a fungal substrate which could be molded, and easily and cheaply preprocessed to precise geometric specifications. The organically derived building materials also incorporate layers of structural reinforcements to improve load bearing and other structural capacities.

The present disclosure relates to a method of sequestering carbon dioxide which comprises the steps of capturing carbon dioxide from an industrial gaseous waste stream and/or the atmosphere, converting a CO.sub.2 from the CO.sub.2 gas stream into a (COOH).sub.2 and combining the (COOH).sub.2, a mono-alcohol (X-OH), preferably CH.sub.3CH.sub.2OH, and a first acid catalyst comprising a H.sub.2SO.sub.4 at a temperature ranging from about 80? C. to about 100? C. and under atmospheric pressure to produce an ester comprising a (COOX).sub.2 and preferably (COOEt).sub.2; and the ester obtained is reacted with a polyol, preferably glycerine to form a polyester, preferably the polyester is a hydrogel. The present disclosure further relates to the use of a hydrogel which is obtainable by said method.

The method grows a mycelial mass over a three-dimensional lattice such that a dense network of oriented hyphae is formed on the lattice. Growth along the lattice results in mycelium composite with highly organized hyphae strands and allows the design and production of composites with greater strength in chosen directions due to the organized nature of the supporting mycelia structure.

The method grows a mycelial mass over a three-dimensional lattice such that a dense network of oriented hyphae is formed on the lattice. Growth along the lattice results in mycelium composite with highly organized hyphae strands and allows the design and production of composites with greater strength in chosen directions due to the organized nature of the supporting mycelia structure.

This application relates generally to aerial mycelium and methods of making aerial mycelium suitable for use as a food or textile product or ingredient. The aerial mycelium can be grown using a growth matrix provided into a growth environment and introducing aqueous mist into the growth environment. The aqueous mist has a mean mist deposition rate to allow for aerial mycelial growth from the growth matrix.

A mycological composite material is made by inoculating a substrate of fibrous material with an inoculum of mycelial tissue; rolling the inoculated substrate into a roll; and thereafter incubating the rolled inoculated substrate for a time sufficient for the mycelial tissue to grow hyphae that enmesh with the substrate to form a cohesive unified filamentous network with the rolled inoculated substrate being characterized in being flexible. The rolled inoculated substrate is subsequently processed by subjecting lengths of the roll to heat and pressure in molds to form rigid products.

A mycological composite material is made by inoculating a substrate of fibrous material with an inoculum of mycelial tissue; rolling the inoculated substrate into a roll; and thereafter incubating the rolled inoculated substrate for a time sufficient for the mycelial tissue to grow hyphae that enmesh with the substrate to form a cohesive unified filamentous network with the rolled inoculated substrate being characterized in being flexible. The rolled inoculated substrate is subsequently processed by subjecting lengths of the roll to heat and pressure in molds to form rigid products.

A configuration system for a green energy agricultural park includes a mushroom cultivation section (10), a super-intensive breeding section (20), a non-toxic vegetable planting section (30), a poultry breeding section (40), a CAS cold chain section (50), a black soldier fly breeding section (60), a goods collection sales section (70), an electric vehicle charging section (80), and a green energy power generation section (90). The green energy power generation section generates electricity and supplies an electric power to the mushroom cultivation section, the super-intensive breeding section, the non-toxic vegetable planting section, the poultry breeding section, the CAS cold chain section, the black soldier fly breeding section, the goods collection sales section, and the electric vehicle charging section. The black soldier fly breeding section breeds black soldier flies to eat agricultural organic resources produced in the green energy agricultural park and to generate black soldier fly manure.

A configuration system for a green energy agricultural park includes a mushroom cultivation section (10), a super-intensive breeding section (20), a non-toxic vegetable planting section (30), a poultry breeding section (40), a CAS cold chain section (50), a black soldier fly breeding section (60), a goods collection sales section (70), an electric vehicle charging section (80), and a green energy power generation section (90). The green energy power generation section generates electricity and supplies an electric power to the mushroom cultivation section, the super-intensive breeding section, the non-toxic vegetable planting section, the poultry breeding section, the CAS cold chain section, the black soldier fly breeding section, the goods collection sales section, and the electric vehicle charging section. The black soldier fly breeding section breeds black soldier flies to eat agricultural organic resources produced in the green energy agricultural park and to generate black soldier fly manure.