A planting method for morels is disclosed, including the following steps of: (1) preparing spawn; (2) flipping the spawn; (3) managing the humidity; and (4) fruiting for harvesting. The planting method is simple, is easy to learn and promote, has a high yield, and requires few spawn, thereby reducing planting costs and product costs.

A planting method for morels is disclosed, including the following steps of: (1) preparing spawn; (2) flipping the spawn; (3) managing the humidity; and (4) fruiting for harvesting. The planting method is simple, is easy to learn and promote, has a high yield, and requires few spawn, thereby reducing planting costs and product costs.

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.

A planting method for morels is disclosed, including the following steps of: (1) preparing spawns; (2) flipping the spawns; (3) managing the humidity; and (4) fruiting for harvesting. The planting method is simple, is easy to learn and promote, has a high yield, and requires few spawns, thereby reducing planting costs and product costs.

A planting method for morels is disclosed, including the following steps of: (1) preparing spawns; (2) flipping the spawns; (3) managing the humidity; and (4) fruiting for harvesting. The planting method is simple, is easy to learn and promote, has a high yield, and requires few spawns, thereby reducing planting costs and product costs.

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.

A method of growing a single plant in a single growth chamber such that the plant may be continously harvested with the replacement of a nutrient media in the chamber. The method of growing the single plant comprises the step of positioning an immature portion of a plant in a growth pod. The method also comprises positioning the growth pod in an aperture of a cap comprising a material that prevents the transmission of light through the cap. The method also comprises supporting the cap on a housing comprising a material that prevents the transmission of light through the housing. The method further comprises placing a liquid nutrient solution in the housing, such the upper surface of the liquid nutrient solution is lower than the lower surface of the growth pod.

A delivery device and system to supplement CO.sub.2 in an underwater environment without the need for electricity or the use of compressed CO.sub.2. The device consists of a container containing a biological organism such as mycelium and including an exit portal for CO.sub.2 to enter the underwater environment. The device may also incorporate a separation device to delay and control the flow of CO.sub.2. The system requires the device to be held in place through a securing point in the underwater environment. The minimum requirements for the device are described, but in certain instances it will be preferably used with a double-bag or an outer shell housing to protect or aesthetically conceal the placement underwater. The use of this device and system to supplement carbon dioxide in water will span many industries and applications. It will assist with mosquito trapping. It will also supplement CO.sub.2 in underwater growing environments.

A cultivation bag assembly for the cultivation of microbes, fungi and other organisms includes a bag having first and second walls joined along side edges to define a bag interior for containing a food substrate and an organism to be cultivated. At least one of the first and second walls is constructed of a layer of water-vapor permeable material to allow the passage of water vapor therethrough. A bag wall overlay layer formed from gas impermeable layer is releasably coupled to the bag. The overlay layer overlays the layer of water-vapor permeable material to prevent the passage of gases therethrough. The bag wall overlay layer has an opening with a gas filter patch covering the opening to allow the passage of oxygen and carbon dioxide gases through the gas filter patch to and from ambient air to facilitate incubation of the organism within the interior of the bag. The bag wall overlay layer is removable from the bag to allow water vapor to pass through the layer of water-vapor permeable material to ambient air facilitate drying of the bag contents after incubation is complete.

The present invention discloses a bag packing mechanism for mushroom cultivation, which comprises two clamping seats, transport means, air duct, pumping means and push rod. Transport means supply collar. Air duct descends through the collar and extends into a bag from the opening of the bag, the two clamping seats clamp the top portion of the bag to close to the outer periphery of the air duct, the pumping means sucks the top portion, the two clamping seats open, the push rod is lowered to push down the collar to put on the top portion, the pumping means blow to open the top portion, the push rod is further lowered to fold the top portion down, the air duct and putter rise, and then complete the automation of packaging job.