Embodiments of the disclosed technology are directed to devices and/or apparatuses for receiving, housing and displaying plants on surfaces having a repetitive pattern of elevation changes resulting in multiple horizontal planar surfaces of varying elevation. The apparatus may be, for example, a caddy adapted to conform to the staggered pattern of one or more steps, curbs, ledges, and/or walls. The caddy may be further adapted to receive and store, at an angle between 0 degrees and 90 degrees, an elongated planter. In further embodiments, a self-contained planter may be disclosed. The planter may be adapted for receiving soil, planting substrate and/or plants. The self-contained planter may have a base region adapted to conform to the staggered pattern of one or more stepped surfaces.

A rotary garden apparatus, method and system for growing plants comprising an open rotatable cylindrical drum mounted within a structural frame is provided wherein said apparatus comprises an accessible front area permitting access to the drum and grow trays mounted on said drum from the front of the apparatus. The rotating drum portion comprises metal bars which form struts round the periphery of the drum on which grow trays can be mounted. The grow trays are inserted by sliding them along the struts of the drum and they are held in position by arms which extend below the metal struts over which the grow trays slide into position. The inverted T shaped fit between the tray and the strut holds the tray in position during rotation without further securing mechanisms required. The operation and most routine maintenance of the apparatus can all be done from the front of the apparatus thereby permitting multiple apparatus units to be placed side by side in a grow facility or against walls. The apparatus may be stacked one above the other all of which maximizes the number of units which can be present in a defined floor space in a grow facility. A light source comprising a holding tray, a sleeve and at least one bulb as part of a rotary garden apparatus is present in the rotary garden apparatus providing light for growing plants.

A plant-growing tray comprises a plurality of cells, each cell for containing in use a substrate for a plant or a cylindrical stabilised medium for propagating a plant. Each cell is formed from injection-moulded plastic and comprises a cell base and eight inclined side walls extending upwardly from the cell base, and each cell comprises four corner side walls having a corner wall gradient, and four stepped side walls which comprise an upper portion having an upper gradient, a lower portion having a lower gradient, and a step having a step gradient. The step is positioned between the upper portion and the lower portion, and the step gradient is less steep than the gradients of the upper portion and the lower portion of the side wall. Each cell comprises a pair of ribs on each of the four stepped walls, the ribs extending upwards from the cell base. At least a lower portion of the ribs have a rib gradient which is steeper than the gradients of the inclined side walls, and the gradient of the corner side walls is less steep than the upper portion or the lower portion of the stepped walls.

An indoor gardening appliance includes a liner defining a grow chamber and a grow module rotatably mounted within the grow chamber for receiving a plurality of plant pods. A moisture management system includes an evaporator plenum in fluid communication with the grow chamber and a fan assembly that recirculates air from the respective grow chambers and/or the ambient environment through an evaporator positioned within the evaporator plenum. In this manner, chamber humidity may be regulated while water is extracted from the air which may be used by a hydration system to hydrate plants.

The disclosed technology includes hydroponics systems and methods of efficient, configurable nutrient solution grow reservoirs that utilize shared components while creating more space in grow facilities. The hydroponics systems include vertical and horizontal rows or layouts of connected reservoirs that may include movable reservoirs to allow for better user access and reduce aisles, which allows space for more reservoirs in a grow facility. Multiple reservoirs may be connected to one another by irrigation tubing (e.g., as shown in in vertical layouts) or by pipes or irrigation tubing (e.g., as shown in horizontal layouts) and share various multiple system components, such as water pumps, water chillers, air pumps, float valves, and drain out systems. In some implementations, incorporation of the 4″ pipes in the horizontal layouts provides for efficient water circulation in a closed loop configuration throughout the disclosed hydroponic systems.

A tray for a horticultural container. The tray includes a plurality of walls forming an outer perimeter and a plurality of openings encompassed within the perimeter, each opening configured to accept a horticultural container. Each opening includes at least one tab configured to engage a portion of the horticultural container such that the horticultural container is held in place within one of the plurality of openings. The tray is configured to have a low profile to save space, save manufacturing materials, and to improve stacking capabilities. The tray can include a plurality of secondary openings to mitigate soil waste in a filling procedure.

An indoor gardening appliance includes a liner defining a grow chamber and a grow module rotatably mounted within the grow chamber and defining a root chamber. A hydration system is fluidly coupled to the root chamber for selectively implementing a hydration cycle where the root chamber is charged with mist and an air circulation system selectively urges a flow of air through the root chamber to maintain a desired temperature. A controller is configured for stopping the flow of air during the hydration cycle, e.g., to minimize disruption of the hydration cycle. The stopping of the flow of air may be time-based, e.g., based on the start/end times of the hydration cycle, or may be based on moisture level, e.g., as measured by an optical sensor.

The disclosed technology includes hydroponics systems and methods of efficient, configurable nutrient solution grow reservoirs that utilize shared components while creating more space in grow facilities. The hydroponics systems include vertical and horizontal rows or layouts of connected reservoirs that may include movable reservoirs to allow for better user access and reduce aisles, which allows space for more reservoirs in a grow facility. Multiple reservoirs may be connected to one another by irrigation tubing (e.g., as shown in in vertical layouts) or by pipes or irrigation tubing (e.g., as shown in horizontal layouts) and share various multiple system components, such as water pumps, water chillers, air pumps, float valves, and drain out systems. In some implementations, incorporation of the 4″ pipes in the horizontal layouts provides for efficient water circulation in a closed loop configuration throughout the disclosed hydroponic systems.

A method of growing plants in a confined space makes use of containers for plants. The containers are stored using a system including a three-dimensional array of array elements, said three-dimensional array of array elements having a stack of two-dimensional arrays of array elements. Each two-dimensional array has a grid of tracks defining a first track for moving a container in an X-direction, and second tracks for moving the container in a Y-direction. Containers are moved using a shuttle. To improve the use of the space available for growing plants, the containers have to be moved from the first track to a second track efficiently. Thus, moving a container to the second track comprises lifting at least one of the containers and the shuttle by bringing moveable track sections from a relatively low position to a relatively high position, and moving the container to the second array element.

An indoor gardening appliance includes a liner defining a grow chamber and a grow module rotatably mounted within the grow chamber and defining a root chamber. A hydration system is fluidly coupled to the root chamber for selectively implementing a hydration cycle where the root chamber is charged with mist and an air circulation system selectively urges a flow of air through the root chamber to maintain a desired temperature. A controller is configured for stopping the flow of air during the hydration cycle, e.g., to minimize disruption of the hydration cycle. The stopping of the flow of air may be time-based, e.g., based on the start/end times of the hydration cycle, or may be based on moisture level, e.g., as measured by an optical sensor.