A pollination control structure comprises a support; a plurality of support fixings, each support fixing being attached to or integral with the support, and; a barrier member comprising a plurality of barrier member pieces. At least one of the barrier member pieces is releasably attached to at least one of the support fixings by an intermediate fixing. The barrier member piece is releasably attached to the intermediate fixing, and the intermediate fixing is releasably attached to the support fixing.

Disclosed is an environment forming apparatus suitable for biological cultivation in extraterrestrial space. The apparatus includes a shell and a biological cabin configured in an upper space of the shell. A light management system for importing light of biological growth from external world is configured in the upper space, a thermal management system for at least balancing a temperature of the upper space and a water supplying system and configured for providing water for creatures growth are both configured on the shell. The biological cabin and the like are set at the appropriate part of the shell, an environment which is relatively suitable for biological growth or cultivation can be created and simulated on an extraterrestrial star, a condition is provided for ecological cultivation of the extraterrestrial space, an ecosystem of the extraterrestrial space can be formed, and a smooth extraterrestrial space biological experiment process is guaranteed.

Self-supporting inflatable grow tents include a base surface, a top surface, and a plurality of sidewalls. The sidewalls include an integrated lighting system. The inflatable grow tents include a plurality of support members configured to structurally support the grow tent when inflated, and an air circulation assembly including an air blower and a carbon filter. The grow tents include a lighting system configured to provide a standard deviation of average photosynthetic active radiation that is from about 2 to about 8 within the grow tent when the lighting system is active.

Self-supporting inflatable grow tents include a base surface, a top surface, and a plurality of sidewalls. The sidewalls include an integrated lighting system. The inflatable grow tents include a plurality of support members configured to structurally support the grow tent when inflated, and an air circulation assembly including an air blower and a carbon filter. The grow tents include a lighting system configured to provide a standard deviation of average photosynthetic active radiation that is from about 2 to about 8 within the grow tent when the lighting system is active.

A system and method for generating high-yield plant production is disclosed. The system includes a container, a growing station, and a monitoring system. The growing station includes vertical racks, a lighting system, an irrigation system, a climate control system, and a ventilation system. The monitoring system monitors all of the systems in the growing station, as well as the environment within the container, to provide real-time data and alerts to a user.

A system and method for generating high-yield plant production is disclosed. The system includes a container, a growing station, and a monitoring system. The growing station includes vertical racks, a lighting system, an irrigation system, a climate control system, and a ventilation system. The monitoring system monitors all of the systems in the growing station, as well as the environment within the container, to provide real-time data and alerts to a user.

A self-contained system for cultivating plants using a combination of aeroponic and hydroponic processes includes a container having successive size reductions to support plant cups, a liquid distribution device, and to provide a reservoir for storing a water and nutrient solution.

The present invention is a compact plant enclosure intended for use in locations with peripheral space restrictions. The top and one side of the enclosure form a continuous curved face which comprises multiple translucent flexible access panels that can be slid along guide channels incorporated into the sides of the curved frame components on either side of the flexible panels. The guide channels and flexible panel edges may incorporate retention features that limit the lateral movement of the flexible access panels. The opposing wall may be comprised of a single fixed translucent vertical panel or multiple vertical access panels. The remaining two vertical sides of the plant enclosure each comprise a fixed, translucent rigid panel. In another embodiment of the present invention, multiple distinct intermediate segments of the enclosure are defined by interstitial curved and vertical frame components supporting adjacent sets of flexible access and opposing vertical panels.

The present invention is a compact plant enclosure intended for use in locations with peripheral space restrictions. The top and one side of the enclosure form a continuous curved face which comprises multiple translucent flexible access panels that can be slid along guide channels incorporated into the sides of the curved frame components on either side of the flexible panels. The guide channels and flexible panel edges may incorporate retention features that limit the lateral movement of the flexible access panels. The opposing wall may be comprised of a single fixed translucent vertical panel or multiple vertical access panels. The remaining two vertical sides of the plant enclosure each comprise a fixed, translucent rigid panel. In another embodiment of the present invention, multiple distinct intermediate segments of the enclosure are defined by interstitial curved and vertical frame components supporting adjacent sets of flexible access and opposing vertical panels.

A container for growing plants includes a bottom wall, a first side wall extending perpendicular to the bottom wall, and a second side wall extending perpendicular to the bottom wall and parallel to the first side wall such that the bottom wall, the first side wall, and the second side wall at least partially define a plant growing chamber. Furthermore, the container includes a lid configured to selectively occlude access to the plant growing chamber. Additionally, one of the bottom wall, the first or second side walls, or the lid includes a rail and another of the bottom wall, the first or second side walls, or the lid defines a groove such that the rail of the container is configured to be received within a groove of a first adjacent container and the groove of the container is configured to receive a rail of a second adjacent container.