Storage, growing system and methods for storing, germinating, propagating and or growing living organisms, exemplary systems including stackable growth tray(s) containing: a drainage system, the drainage system including: an inclined growing surface, inclined in a direction to at least one drainage hole; a drainage routing structure positioned over the at least one drainage hole, and having a down-pipe and a connecting routing pipe, wherein the down-pipe is for receiving fluid from an adjacent-above stackable item and transmitting the fluid to an adjacent-below down-pipe or a drain-pipe, and the connecting routing pipe is for receiving fluid from an adjacent-above drainage hole and routing the fluid to the down-pipe, and wherein fluid propagating from the inclined growing surface or an adjacent-above stackable item is directed through the growth tray to a down-steam point in the drainage system.

Facility layouts and configurations for an automated crop production system for controlled environment agriculture. In particular implementations, the core of the facility comprises a controlled growth environment and a central processing system. The controlled growth environment includes systems for exposing crops housed in modules, such as grow towers, to controlled environmental conditions. The central processing system may include various stations and functionality both for preparing crop-bearing modules to be inserted in the controlled growth environment for harvesting crops from the crop-bearing modules after they have been extracted from the controlled growth environment, and for cleaning or washing crop-hearing modules for re-use. The remaining aspects of the crop production facility—such as seeding stations, propagation facilities, packaging stations and storage facilities—are arranged to achieve one or more desired efficiencies relating to capital expenditures or operating costs associated with an automated crop production facility.

A Vertical-Hive Green Box (or V-Hive Green Box) is a modular cultivation system utilized in a modular Vertical Farm or Plant Factory, as well as a warehouse-type or greenhouse-type of vertical farm or plant factory. The V-Hive Green Box includes growing boards, lighting boards, and an irrigation system arranged within a frame structure to maximize the quantity of crops that can be grown within an available volume of space in a modular Vertical Farm unit, warehouse or greenhouse per unit time. The V-Hive Green Box can also include aquaculture boards that can be used for aquaculture of aquatic fish and plants.

A vertical farming structure having vertical grow towers and associated conveyance mechanisms for moving the vertical grow towers through a controlled environment, while being exposed to controlled lighting, airflow, humidity and nutritional support. The present disclosure describes a reciprocating cam mechanism that provides a cost-efficient mechanism for conveying vertical grow towers in the controlled environment. The reciprocating cam mechanism can be arranged to increase the spacing of the grow towers as they are conveyed through the controlled environment to index the crops growing on the towers. The present disclosure also describes an irrigation system that provides aqueous nutrient solution to the grow towers.

The invention concerns a system for cultivating plant products without soil comprising a plurality of shelves for cultivating plant products. The shelves have a reference axis and comprise: a supporting frame, a plurality of cultivation bars which have an approximately rectilinear shape, extend along respective longitudinal axes, and are coupled to the supporting frame so as to be arranged approximately coplanar and alongside one another, and have the respective longitudinal axes parallel to the reference axis and mechanical spacing members, which are interleaved between the adjacent cultivation bars, and are each structured so that the actuation of a mechanical spacing member causes a variation of the distance transverse to the reference axis, between two cultivation bars immediately adjacent to the same member. The invention also concerns a method for cultivating plant products.

A method and system for moving a plant growing container, wherein the method makes use of a system that includes a cultivation track, a conveying track, a lift and a guide assembly. The method includes the initially moving the plant growing container at the first level along a first direction from a first end of the cultivation track onto the lift next to the first end of the cultivation track. From there, the plant growing container is lowered from the first level to the second level onto the conveying track. To reduce blocking of the system, the guide is movable to a third level higher than the first level. Furthermore, the method further includes guiding the plant growing container by means of moving said guide to said third level once the container has been moved onto the lift.

An automated modular plant growing system includes a rack structure with primary guiding tracks and secondary guiding tracks transverse to each other, and upper guiding tracks in parallel and above the primary guiding tracks. The automated modular plant growing system also includes a plurality of mobile modules detachably connected to the upper guiding tracks and to a nutrient solution supply system.

A vertical farming structure having vertical grow towers and associated conveyance mechanisms for moving the vertical grow towers through a controlled environment, while being exposed to controlled lighting, airflow, humidity and nutritional support. The present disclosure describes a reciprocating cam mechanism that provides a cost-efficient mechanism for conveying vertical grow towers in the controlled environment. The reciprocating cam mechanism can be arranged to increase the spacing of the grow towers as they are conveyed through the controlled environment to index the crops growing on the towers. The present disclosure also describes an irrigation system that provides aqueous nutrient solution to the grow towers.

Facility layouts and configurations for an automated crop production system for controlled environment agriculture. In particular implementations, the core of the facility comprises a controlled growth environment and a central processing system. The controlled growth environment includes systems for exposing crops housed in modules, such as grow towers, to controlled environmental conditions. The central processing system may include various stations and functionality both for preparing crop-bearing modules to be inserted in the controlled growth environment, for harvesting crops from the crop-bearing modules after they have been extracted from the controlled growth environment, and for cleaning or washing crop-bearing modules for re-use. The controlled growth environment may include vertical farming structure having vertical grow towers and associated conveyance mechanisms for moving the vertical grow towers along one or more grow lines. The conveyance mechanisms may include a return transfer mechanism that creates a return or u-shaped path for each grow line.

A drive unit in a controlled agricultural environment increases a distance between an alignment element and a drive element in order to receive a plant support structure that is oriented non-vertically so that the plant support structure rests on the drive element or the alignment element. The drive unit decreases the distance between the alignment element and the drive element so that the alignment element or the drive element rests on the plant support structure. The drive element conveys the plant support structure along a direction of conveyance.