A cooling device according to the present invention includes a housing configured to accommodate fungi. Warm air enters the housing through an inlet located in the housing. The air flows through the housing, which holds fungi. The air exits the housing and can be driven by an exhaust fan. In some embodiments, a HEPA filter is included to purify the air and prevent dispersal of fungal spores.

A cooling device according to the present invention includes a housing configured to accommodate fungi. Warm air enters the housing through an inlet located in the housing. The air flows through the housing, which holds fungi. The air exits the housing and can be driven by an exhaust fan. In some embodiments, a HEPA filter is included to purify the air and prevent dispersal of fungal spores.

The present invention provides a wind power device capable of effectively suppressing the generation of an imbalance between air and carbon dioxide in a plurality of cultivation portions arranged along a specified direction, and a growing system provided with such a wind power device. The wind power device (100) of the present invention provides wind to objects cultivated in a plurality of cultivation portions (10) disposed along a specified direction (Dm), and the wind power device is provided with a movement unit (120) configured to be capable of reciprocally moving on a movement path (Am) along the specified direction (Dm) and capable of adjusting the period of the reciprocal movement; and at least one blower (131, 132) configured to move along with the movement unit (120).

An organic growth substrate, which supports mushroom growth from an inoculum of the species to be grown, is disposed within a growing apparatus impervious to microbiological contamination from an external environment and operationally associated with an environmental control apparatus. The environmental control apparatus modulates air, water, thermal, and light inputs to, and outputs from, one or more growing apparatuses to establish and maintain the desired environment within the growing apparatus. The system operates via a plurality of sensing, digital processing and mechanical components governed by software algorithms and operator input. A lyophilizer freeze dries harvested mushrooms for storage stability purposes. The system is configured to exchange information with the operator via a user interface and wireless connection to remote devices.

An organic growth substrate, which supports mushroom growth from an inoculum of the species to be grown, is disposed within a growing apparatus impervious to microbiological contamination from an external environment and operationally associated with an environmental control apparatus. The environmental control apparatus modulates air, water, thermal, and light inputs to, and outputs from, one or more growing apparatuses to establish and maintain the desired environment within the growing apparatus. The system operates via a plurality of sensing, digital processing and mechanical components governed by software algorithms and operator input. A lyophilizer freeze dries harvested mushrooms for storage stability purposes. The system is configured to exchange information with the operator via a user interface and wireless connection to remote devices.

A monokaryotic mycelium sheet producing system for creating a sheet of monokaryotic mycelial material. The mycelium sheet producing system includes a culture unit, a spore stock unit, a plating unit, a section unit, a sub-plating unit, an expanding unit and a colonization unit. The culture unit prepares a monokaryon culture. The spore stock unit grows a plurality of fruit bodies in sterile laboratory conditions to create a spore stock. The plating unit performs a peroxide-based spore rescue and a plating process. The section unit is adaptable to section robust hyphae. The sub-plating unit sub-plates and expands the robust hyphae onto a spawn grain master. The expanding unit subsequently expands the spawn grain master into appropriate production of spawn volume. The colonization unit is adaptable to perform a subsequent colonization of mycelium substrate thereby creating a substantially defect free sheet of mycelium.

A monokaryotic mycelium sheet producing system for creating a sheet of monokaryotic mycelial material. The mycelium sheet producing system includes a culture unit, a spore stock unit, a plating unit, a section unit, a sub-plating unit, an expanding unit and a colonization unit. The culture unit prepares a monokaryon culture. The spore stock unit grows a plurality of fruit bodies in sterile laboratory conditions to create a spore stock. The plating unit performs a peroxide-based spore rescue and a plating process. The section unit is adaptable to section robust hyphae. The sub-plating unit sub-plates and expands the robust hyphae onto a spawn grain master. The expanding unit subsequently expands the spawn grain master into appropriate production of spawn volume. The colonization unit is adaptable to perform a subsequent colonization of mycelium substrate thereby creating a substantially defect free sheet of mycelium.

A modular hydroponic tower array fixture system for the growth of organisms such as plants and fungi on arrays of hydroponic towers, allowing for the insertion and removal of individual towers from the array, is provided. Methods for the production of organisms such as plants and fungi using a modular hydroponic tower array fixture system are also provided herein.

For indoor mushroom cultivation, a method of irrigating the mushrooms includes drip irrigation pipes in the bed. The drip irrigation pipes can be disposed in a casing layer that overlies a substrate layer, and irrigation can be according to measurements taken in the environment outside of the bed.

According to aspect of the present invention there is provided process for growing plant with small element comprising of steps that involve shooting or firing high frequency to a solution containing minerals that affect plant growth. Then there was a high-frequency launch into the colloid body. Finally, the nanoparticles are created. The nanoparticle will float to the root of plant, which is suspended in the air to enrich plants and provide enough nutrients to grow. The process of plant cultivation according to the present invention was invented to develop resource reducing cultivation.