A system and method are provided for the indoor and outdoor cultivation of larger fruiting plants. Improved lighting techniques, plant layouts, and space utilization are provided to improve the quality and yields of harvested products from large fruiting plants on a per plant and unit area basis. The uniformity of artificial light is improved from the top to the bottom of tall plants and vines, and overcome the lack of light penetration through the canopy of the plant by changing the orientation of lights from a horizontal to vertical alignment along the side of the plant verses over the top of the canopy, as well as increasing the number of light sources to reduce shading. Plants are trained to grow in specific directions and orientations in a grid system to enable an optimal and uniform light distribution and to improve space utilization in a given growing area.

A plant-growing tray for containing cylindrical stabilised media for growing plants comprises an array of flared columns, a lower end of the columns being wider than an upper end. The columns define an array of cells therebetween for containing cylindrical stabilised media, and a column comprises one or more contact edges defined by an intersection between a wall of the flared column and a virtual cylindrical surface in a cell, such that the contact edges are suitable for contacting a cylindrical stabilised medium positioned in the cell.

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.

In accordance with embodiments of the invention, there are provided automated plant training systems and related methods. An automated plant training system is designed to train medium to tall plants to grow in a height restricted space by adjusting the plant's direction of growth through the use of phototropism. The device can physically control the plant's main stem, branches and foliage from excessive vertical growth.

An automated plant cultivation system is provided having multi-tiered vertically arranged horizontal magazine structures each employing seed or plant capsules with a fluid circulation and illumination and communication network controlled by an on-board processor. Particularly, the system includes a magazine structure having seed/plant capsules within seed/plant reservoirs alternately arranged between at least one of a light source substantially concealed from direct viewing. A fluid channel extends across a long axis of the magazine structure, wherein the magazine structure is adapted for use of seed/plant capsules with nutrient composite plant growth cultivation, hydroponic plant growth cultivation, aeroponic plant growth cultivation methods or combinations thereof.

A plant plug holding unit is provided, the plant plug holding unit including at least one plant plug holder. The plant plug holding unit, which is configured to be inserted into a cut-out in a hydroponic tower face plate, includes an edge member that encircles the unit and is sealed to the rear surface of the front tower face. Each individual plant plug holder of the plant plug holding unit includes (i) a base member configured to support a plant plug and which extends rearward from the edge member and into the hydroponic tower cavity; (ii) a top shroud member that inhibits leakage as well as plug erosion; (iii) a pair of side members that maintain the position of the plant plug within the plug holder; and (iv) a plurality of open regions configured to promote water drainage from the plant plug.

A sprout lid for use with a container to sprout seeds and or beans is provided which may include a recess feature which may allow the container to be filled with water without removing the sprout lid from the container, as well as allowing proper airflow in the container. The sprout lid may also be used to rinse, strain, and drain seeds and or beans in the container.

A system for growing a plant (1) in an at least partly conditioned environment includes a cultivation base (11) for receiving a culture substrate (3) with a root system (4) of the plant therein. Root temperature control elements (12) are provided which are able and adapted to impose a predetermined root temperature on the root system, and lighting elements (20,21,22) which are able and adapted to expose leaves of the plant to actinic artificial light. Leaf heating elements are also provided, which are able and adapted to impose on the leaf of the plant a leaf temperature varying from an ambient temperature. In a method for growing the plant a carbon dioxide assimilation management of a leaf system of the plant is thus influenced, and a supply of actinic light, the root temperature and the carbon dioxide assimilation management are adapted to each other.

A system for growing a plant (1) in an at least partly conditioned environment includes a cultivation base (11) for receiving a culture substrate (3) with a root system (4) of the plant therein. Root temperature control elements (12) are provided which are able and adapted to impose a predetermined root temperature on the root system, and lighting elements (20,21,22) which are able and adapted to expose leaves of the plant to actinic artificial light. Leaf heating elements are also provided, which are able and adapted to impose on the leaf of the plant a leaf temperature varying from an ambient temperature. In a method for growing the plant a carbon dioxide assimilation management of a leaf system of the plant is thus influenced, and a supply of actinic light, the root temperature and the carbon dioxide assimilation management are adapted to each other.

A hydroponic plant cultivation apparatus includes a reservoir with an opening. A plurality of planting modules can be stacked above the opening. Each module includes at least one planting port, a module conduit aperture, a top end, and a bottom end configured to releasably engage the opening or the top end of another module. A conduit fluidly communicable with the reservoir is receivable through the module conduit apertures. A fluid distributor is engageable with a top end of the conduit. A fluid contained in the reservoir is selectively circulatable from the reservoir through the conduit to the fluid distributor, where the fluid is redirected down the interior of the modules and back to the reservoir when the modules are stacked above the opening in the reservoir, the conduit is received in the module conduit apertures and fluidly communicated with the reservoir, and the fluid distributor is engaged with the conduit.