Provided are: a plant cultivation method for improving the crop acreage of plants that are cultivated indoors, a plant cultivation system, and a rack that is comprised in the plant cultivation system. The plant cultivation method of the present invention comprises: setting a cultivation vessel 2 for cultivating a plant P in a rack 1; adjacently arranging a plurality of the racks 1 on a travel line in order of growth of the plant P; intermittently advancing the rack 1 according to a growth state of the plant P; and separating the first rack 1 from the following rack(s) 1, and making a new rack 1 adjacent to the last rack 1 of the following rack(s) 1.

One variation of a method for automating transfer of plants within an agricultural facility includes: dispatching a loader to autonomously deliver a first moduledefining a first array of plant slots at a first density and loaded with a first set of plants at a first growth stagefrom a first grow location within an agricultural facility to a transfer station within the agricultural facility; dispatching the loader to autonomously deliver a second moduledefining a second array of plant slots at a second density less than the first density and empty of plantsto the transfer station; recording a module-level optical scan of the first module; extracting a viability parameter of the first set of plants from features detected in the module-level optical scan; and if the viability parameter falls outside of a target viability range, rejecting transfer of the first set of plants from the first module.

The present invention provides a flower pot which may be easily opened to facilitate placing or removing of the potted plant therein. The flower pot has at least one of the sidewall divided into two sidewall portions, and an opposing sidewall is provided with a hinge arrangement to allow for separating the two sidewall portions from each other, such that a front of the flower pot is opened for convenient placing or removing of the potted plant inside therein as desired without damaging the plant. Further, a locking arrangement is provided to hold together the two sidewall portions after the transplantation operation has been performed.

The present invention relates to a distributor apparatus adapted for positioning individual pieces of a length of growth medium cut into pieces of suitable size into a propagation tray. The distributor apparatus comprises a plurality of distributor units configured to move between a loading position and an unloading position. Each distributor unit comprises an open-ended channel or cavity adapted for receiving a whole number of growth medium pieces. The distributor units, in a loading position, are positioned relatively to each other such that their open-ended channels or cavities are disposed in continuation to each other to form a receiving unit with an open-ended channel or cavity adapted for receiving a single length of growth medium pieces. The distributor units, when in an unloading position, are rotated, relative to their loading position, such that their open-ended channels or cavities are disposed parallel relative to each other.

A selective transplanter is provided for transplanting seedlings from a tray to seedling planting apparatus. The tray includes a plurality of cells for holding plugs of growing medium containing seedlings. The transplanter is arranged to eject plugs from the cells of the tray to a conveyor which conveys the plugs to the seedling planting apparatus. The transplanter is arranged to remove plugs that do not contain germinated seedlings from the conveyor at a removal position before they are transferred to the seedling planting apparatus. A seedling retention roller engages with plant material of the seedlings projecting from the plugs at the removal position before the plugs are transferred to the seedling planting apparatus, preventing removal of plugs containing seedlings with projecting plant material. The transplanter provides the advantage that the plugs containing seedlings can be planted in rows in a field without dud plugs being planted, leaving the rows substantially gap free.

A container farm provides a grow zone and a work zone within an enclosure. Plants are grown in vertical grow towers within the grow zone supported by a rotatable carousel grow structure. The grow towers can be moved within the grow zone to a location in which they are accessible from the work zone. A seedling station can be provided within the work zone. Other systems, including an irrigation system, a lighting system, and a climate control system, can be provided to support the growth of plants within the container.

One variation of a method for automating transfer of plants within an agricultural facility includes: dispatching a loader to autonomously deliver a first moduledefining a first array of plant slots at a first density and loaded with a first set of plants at a first growth stagefrom a first grow location within an agricultural facility to a transfer station within the agricultural facility; dispatching the loader to autonomously deliver a second moduledefining a second array of plant slots at a second density less than the first density and empty of plantsto the transfer station; recording a module-level optical scan of the first module; extracting a viability parameter of the first set of plants from features detected in the module-level optical scan; and if the viability parameter falls outside of a target viability range, rejecting transfer of the first set of plants from the first module.

A vegetation hanger includes a linear plate and an aperture. The linear plate includes a first edge, a second edge, a first end portion, and a second end portion. The first edge includes at least one ridge disposed along the first edge. The aperture is disposed centrally along the linear plate and configured to slidably engage with a bar.

A method for operating a greenhouse system with block storage, at least one block storage container and at least one vehicle. Each block storage container has a carrier frame and a plant receptacle, the plant receptacle being detachably engaged with the carrier frame, the block storage having at least one first zone and one second zone, and at least one first carrier frame and at least one second carrier frame, the plant receptacle in the first zone being detachably engaged with the first carrier frame; and the plant receptacle being subsequently transferred into the second zone, the plant receptacle being transferred from the first carrier frame to the second carrier frame as part of the transferal from the first zone into the second zone, the plant receptacle in the second zone being detachably engaged with the second carrier frame.

A grow system. The system includes growing plants in grow modules that are individually moveable. The plants grow in trays where roots never touch the water supply. The plumbing to the grow modules is a low flow, one way flow continual drip system that is hands free. A mobile robot can navigate around a growspace, bring any grow module from one location to another, and perform growspace operations. The growspace is a control space with data source zones and a control space manager. The control space manager can collect data and control different variables across different data source zones in order to determine optimal policies and conditions for data source growth and generation.