An environment-controllable cultivation device for Morchella esculenta planting is provided, relating to the technical field of Morchella esculenta planting. The device includes a fixing seat and a Morchella esculenta cultivation cover. The Morchella esculenta cultivation cover is fixedly connected with the fixing seat, and a supporting top plate is fixedly installed at a top of the Morchella esculenta cultivation cover, and a water tank is fixedly installed on the supporting top plate; a mounting plate, where the mounting plate is located in the Morchella esculenta cultivation cover and is fixedly connected with the supporting top plate; and a cultivating mechanism, where the cultivating mechanism is located in the Morchella esculenta cultivation cover and is connected with the mounting plate, and the cultivating mechanism is also connected with the water tank. The cultivating mechanism includes a variable detection assembly, a soil moisturizing assembly and a cultivation assembly.

An environment-controllable cultivation device for Morchella esculenta planting is provided, relating to the technical field of Morchella esculenta planting. The device includes a fixing seat and a Morchella esculenta cultivation cover. The Morchella esculenta cultivation cover is fixedly connected with the fixing seat, and a supporting top plate is fixedly installed at a top of the Morchella esculenta cultivation cover, and a water tank is fixedly installed on the supporting top plate; a mounting plate, where the mounting plate is located in the Morchella esculenta cultivation cover and is fixedly connected with the supporting top plate; and a cultivating mechanism, where the cultivating mechanism is located in the Morchella esculenta cultivation cover and is connected with the mounting plate, and the cultivating mechanism is also connected with the water tank. The cultivating mechanism includes a variable detection assembly, a soil moisturizing assembly and a cultivation assembly.

A method of growing an extra-particle aerial mycelium employs electrostatically charged mist to control mist deposition uniformity in a growth environment, and on a growth matrix (or growing extra-particle aerial mycelium on a growth matrix) comprising nutritive substrate and a fungus in a growth environment with a predetermined environment of humidity, temperature, carbon dioxide, and oxygen. Control of mist deposition by electrostatically charging mist allows for control of the morphology and uniformity of the extra-particle aerial mycelium produced, independent of airflow uniformity, growth environment size, and structural obstacles that may be present within a growth environment. Control of mist deposition by electrostatically charging mist also offers the potential for targeted mist application where it might be needed most for fungal organism growth.

A mushroom grow assembly, comprising a top cover, a base assembly, a post, a transparent cover, and an extractor fan. 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, comprising a top cover, a base assembly, a post, a transparent cover, and an extractor fan. 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 device and method for irrigating and providing nutrients to plants and fungi, having a supply unit, which has an inlet that can be connected at least indirectly to a water and/or nutrient solution supply and which has an outlet through which water and/or nutrient solution can be dispensed in at least two locations that are positioned at different heights with respect to a vertical. The solution features the fact that the supply unit has a drive train (8), which can be connected to a drive unit, and at the outlet, has at least one nozzle, which is coupled to the drive train and is for dispensing the water and/or nutrient solution, wherein based on an activation of the drive train, the nozzle is movable to at least two locations positioned at different heights.

A device and method for irrigating and providing nutrients to plants and fungi, having a supply unit, which has an inlet that can be connected at least indirectly to a water and/or nutrient solution supply and which has an outlet through which water and/or nutrient solution can be dispensed in at least two locations that are positioned at different heights with respect to a vertical. The solution features the fact that the supply unit has a drive train (8), which can be connected to a drive unit, and at the outlet, has at least one nozzle, which is coupled to the drive train and is for dispensing the water and/or nutrient solution, wherein based on an activation of the drive train, the nozzle is movable to at least two locations positioned at different heights.

A mushroom growing appliance includes a cabinet, a grow chamber defined within the cabinet, a water reservoir positioned within the grow chamber for receiving water, and a liquid droplet assembly fluidly coupled to the water reservoir for selectively generating a liquid mist from the water stored in the water reservoir.

A mushroom growing appliance includes a cabinet, a grow chamber defined within the cabinet, a water reservoir positioned within the grow chamber for receiving water, and a liquid droplet assembly fluidly coupled to the water reservoir for selectively generating a liquid mist from the water stored in the water reservoir.

A smart terraponic gardening system is provided that includes a first reservoir configured to contain a liquid and a second reservoir configured to contain a growing medium for a plant or fungus. A light source and a watering system are provided. A control unit is in electronic communication with the light source and the watering system. At least one sensor of a camera, a temperature sensor, or a humidity sensor is provided in signal communication with the control unit to adjust growing conditions based on the sensor output. In some instances, the control unit is programmed to maintain growing conditions for a specific plant of fungus growing in the second reservoir. The program in some instances is associated with a library of target plants or fungi, and their associated idealized growing conditions.