The process for producing mycelium biomaterial provides fresh oxygen to the growing mycelium biomaterial while removing waste heat and waste carbon dioxide by forced aeration through large volumes of material. In a first phase of fungal expansion, humidified air at a programmed temperature is passed upwardly and through a fungal inoculated substrate of discrete particles to allow the fungal inoculum to expand and dominate the substrate. Nutrient is added to the inoculated mixture and a second phase of fungal expansion is performed wherein humidified air at a programmed temperature is passed upwardly and through the nutrient enriched fungal inoculated substrate to allow the fungal inoculum to bond the discrete particles into a self-supporting biocomposite.

The process and apparatus of the invention allows for the processing of grown materials bound by mycelium at depths of greater than 6″ and particularly in the range of from 24″ to 28″.

The process for producing mycelium biomaterial provides fresh oxygen to the growing mycelium biomaterial while removing waste heat and waste carbon dioxide by forced aeration through large volumes of material. In a first phase of fungal expansion, humidified air at a programmed temperature is passed upwardly and through a fungal inoculated substrate of discrete particles to allow the fungal inoculum to expand and dominate the substrate. Nutrient is added to the inoculated mixture and a second phase of fungal expansion is performed wherein humidified air at a programmed temperature is passed upwardly and through the nutrient enriched fungal inoculated substrate to allow the fungal inoculum to bond the discrete particles into a self-supporting biocomposite.

The process and apparatus of the invention allows for the processing of grown materials bound by mycelium at depths of greater than 6″ and particularly in the range of from 24″ to 28″.

The present disclosure relates to the field of ecological restoration of a coal gangue hill, and in particular, to a solid waste-based porous material, a method for preparing the solid waste-based porous material, and a method of ecological restoration of the coal gangue hill by applying the solid waste-based porous material. A coal-based solid waste restoration material and mycorrhizal solid bacterial agent are mixed to restore the coal gangue hill, the coal-based solid waste restoration material is prepared by mixing coal-based solid waste porous materials, low-rank coal, and waste organic matter and adding a microbial quickly decomposition agent for aerobic fermentation and standing.

The present disclosure relates to the field of ecological restoration of a coal gangue hill, and in particular, to a solid waste-based porous material, a method for preparing the solid waste-based porous material, and a method of ecological restoration of the coal gangue hill by applying the solid waste-based porous material. A coal-based solid waste restoration material and mycorrhizal solid bacterial agent are mixed to restore the coal gangue hill, the coal-based solid waste restoration material is prepared by mixing coal-based solid waste porous materials, low-rank coal, and waste organic matter and adding a microbial quickly decomposition agent for aerobic fermentation and standing.

A device and a method for breeding blueberry-specific mycorrhizal fungi. The device includes a container, where a bottom of the container is laid with perlite to form a perlite layer; an absorbent cotton is arranged on the perlite layer; a hole for planting is provided in the absorbent cotton and blueberry tissue culture seedlings or moss seedlings are placed in the hole; and a spore transfer solution is provided around the blueberry tissue culture seedlings or moss seedlings. When used as a bacterial fertilizer for inoculation in the field, the pieces of absorbent cotton are buried directly around the blueberry roots; while used for research, one of the pieces of the absorbent cotton is washed with sterile water and filtered with a filter paper to obtain mycorrhizal fungi spores.

A device and a method for breeding blueberry-specific mycorrhizal fungi. The device includes a container, where a bottom of the container is laid with perlite to form a perlite layer; an absorbent cotton is arranged on the perlite layer; a hole for planting is provided in the absorbent cotton and blueberry tissue culture seedlings or moss seedlings are placed in the hole; and a spore transfer solution is provided around the blueberry tissue culture seedlings or moss seedlings. When used as a bacterial fertilizer for inoculation in the field, the pieces of absorbent cotton are buried directly around the blueberry roots; while used for research, one of the pieces of the absorbent cotton is washed with sterile water and filtered with a filter paper to obtain mycorrhizal fungi spores.

The process for producing mycelium biomaterial provides fresh oxygen to the growing mycelium biomaterial while removing waste heat and waste carbon dioxide by forced aeration through large volumes of material. In a first phase of fungal expansion, humidified air at a programmed temperature is passed upwardly and through a fungal inoculated substrate of discrete particles to allow the fungal inoculum to expand and dominate the substrate. Nutrient is added to the inoculated mixture and a second phase of fungal expansion is performed wherein humidified air at a programmed temperature is passed upwardly and through the nutrient enriched fungal inoculated substrate to allow the fungal inoculum to bond the discrete particles into a self-supporting biocomposite. The process and apparatus of the invention allows for the processing of grown materials bound by mycelium at depths of greater than 6″ and particularly in the range of from 24″ to 28″.

The process for producing mycelium biomaterial provides fresh oxygen to the growing mycelium biomaterial while removing waste heat and waste carbon dioxide by forced aeration through large volumes of material. In a first phase of fungal expansion, humidified air at a programmed temperature is passed upwardly and through a fungal inoculated substrate of discrete particles to allow the fungal inoculum to expand and dominate the substrate. Nutrient is added to the inoculated mixture and a second phase of fungal expansion is performed wherein humidified air at a programmed temperature is passed upwardly and through the nutrient enriched fungal inoculated substrate to allow the fungal inoculum to bond the discrete particles into a self-supporting biocomposite. The process and apparatus of the invention allows for the processing of grown materials bound by mycelium at depths of greater than 6″ and particularly in the range of from 24″ to 28″.

Device for delivering at least a layer of compost and casing soil to a shelving for growing mushrooms, comprising a first conveyor, on which in a downstream direction are arranged a first hopper with a receiving opening for receiving compost and a dispensing opening for delivering a compost layer on the first conveyor and a second hopper with a receiving opening for receiving casing soil and a dispensing opening for delivering casing soil on the compost layer wherein at least one separator for separating in a direction perpendicular to the downstream direction at least two fractions of the layer of compost with casing soil.

Device for delivering at least a layer of compost and casing soil to a shelving for growing mushrooms, comprising a first conveyor, on which in a downstream direction are arranged a first hopper with a receiving opening for receiving compost and a dispensing opening for delivering a compost layer on the first conveyor and a second hopper with a receiving opening for receiving casing soil and a dispensing opening for delivering casing soil on the compost layer wherein at least one separator for separating in a direction perpendicular to the downstream direction at least two fractions of the layer of compost with casing soil.