Disclosed herein is a system for growing and harvesting living matter. The system includes trays. The system also includes a racking portion, including at least one rack having shelves vertically spaced apart from each other and a robot selectively operable to deliver the trays to and retrieve the trays from the shelves. The system further includes a processing portion, including a harvester configured to receive the trays from the shelves and to remove living matter from the trays, and a seeder configured to receive the trays from the harvester and to distribute seed to the trays. The system additionally includes an electronic controller operable to autonomously control operation of the robot to deliver the trays, after seeded by the seeder, to the shelves and to retrieve the trays, when the seed has grown into the living matter, from the shelves.

An automated vertical farming system includes a framework structure forming a grid storage arrangement. One or more module handling vehicles are arranged to travel and transport modules along a rail system. A control system is configured to control the travel and operation of the one or more module handling vehicles. Stackable growth modules are arranged to support growing plants, the growth modules having a footprint corresponding to that of a column of the framework structure, such that the growth modules may be arranged in stacks in the columns. The growth modules allow plants to grow horizontally, and also provide a non-drip watering system for watering the plants.

A flower gift kit, the gift kit comprising: a flower; an enclosure; a presentation tray for the flower inserted in the enclosure; an insert configured to be flat beneath the presentation tray and between the presentation tray and the enclosure of the flower; wherein the insert comprises pre-determined fold lines; and wherein the insert is user-erectable into a 3D stand for the flower using the predetermined fold lines.

A plant growing system comprising a growing panel and a porous air hose coupled to the growing panel. The growing panel includes a plurality of openings for receiving a plurality of plant receptacles. The plurality of openings are arranged in a plurality of parallel lines on the growing panel, and the porous air hose extends along the growing panel between at least two of the parallel lines.

A plant growing system comprising a growing panel and a porous air hose coupled to the growing panel. The growing panel includes a plurality of openings for receiving a plurality of plant receptacles. The plurality of openings are arranged in a plurality of parallel lines on the growing panel, and the porous air hose extends along the growing panel between at least two of the parallel lines.

A package for a living, edible plant includes a tray having a bottom wall and four side walls defining an open, upper end of said tray, and a living, edible plant being having leaves that extend above the open, upper end of said tray. The package has a flexible outer container having a bottom panel extending along a closed lower end of the flexible outer container and side panels extending upwardly from the bottom panel toward an open upper end of the flexible outer container. The tray and the plant are disposed inside the flexible outer container so that the bottom wall of the tray reinforces the bottom panel of the flexible outer container and the side walls of the tray oppose the side panels of the flexible outer container. The upper ends of the side panels of the flexible outer container extend above upper ends of the four side walls of the tray. The upper ends of the leaves extend above the upper ends of the side panels of the flexible outer container and the upper ends of the side panels of the flexible outer container engage the leaves for tucking the leaves inwardly inside the flexible outer container.

Embodiments of the present disclosure relate to a potting apparatus, which includes a drill that is repositionable relative to a pot-driving conveyor such that the potting apparatus may be placed in a first potting configuration or a second potting configuration. In the first potting configuration, the drill is in a first position relative to the pot-driving conveyor such that the apparatus can provide the requisite drilling functionality for potting plant life with smaller vertical profiles. In the second potting configuration, the drill is in a second position relative to the pot-driving conveyor to provide sufficient vertical clearance above the pot-driving conveyor for potting plant life with larger vertical profiles. The potting apparatus may further include a soil delivery system adapted to receive and dispense soil to the pot-driving conveyor and a drive system operatively connected to the pot-driving conveyor.

An apparatus (2) for receiving and depositing plant pots (26) which stand in rows, having at least two receiving channels (4) that are arranged in parallel beside each other and which extend in an extent direction (R) and are provided with lateral delimitations (6). Adjustment of the channel width (24) of the receiving channels (4) with an adjustment apparatus (14), includes the lateral delimitations (6) that are supported in a laterally displaceable and rotationally secure manner on a displacement member (16) which is orientated transversely relative to the extent direction (R) of the receiving channels (4), the lateral delimitations (6) are connected to an adjustable coupling rod linkage (18), the coupling rod linkage (18) form the adjustment apparatus (14), and the coupling rod linkage (18) adjusts the channel width (24) of all the receiving channels (4) by the same value.

A pot for use with system for controlling soil moisture in a plurality of potted plants to perform water deficit experiments includes a body portion having an open top end and a bottom end, and a flange coupled to the body portion adjacent the top end. The flange is configured to engage a platform to hold the body portion within an opening of the platform. The pot also includes a fluid reservoir having a bottom portion located adjacent the bottom end of the body portion, a plurality of vertically extending fluid channels extending upwardly toward the top end of the body portion, a fill opening located at the bottom end of the body portion in communication with the bottom portion of the fluid reservoir, and a check valve coupled to the fill opening to permit fluid to be supplied to the fluid reservoir from the bottom end of the body portion through fill opening and the check valve.

A method for controlling soil moisture to perform water deficit experiments on a plurality of plants located in soil contained within a plurality of pots supported in a plurality of openings of a stationary platform includes lifting the plurality of pots with a plurality of load cell modules and weighing each of the plurality of pots with the load cell modules. The method also includes determining whether each pot needs to be watered based on the weight of the pot and the water deficit experiment, watering the pots through the load cell modules, if necessary, and lowering the plurality of load cell modules so that the plurality of pots are supported by the platform.