A lighting system for a vertical garden includes at least one light ring including a central hub member configured to be removably mounted to the vertical garden, an outer ring member, and a plurality of spoke members extending radially between the central hub member and the outer ring member, a plurality of light sources supported in the outer ring member, and a drive circuit for the plurality of light sources, a power supply, and at least one power connector connected between the drive circuit and the power supply.

An indoor gardening appliance includes a grow module that is seated on a turntable that is rotatably mounted within a grow chamber and is rotated by a drive assembly. A position sensing assembly monitors an angular position using two proximity sensors, such as Hall-effect sensors, mounted below the sump at the same circumferential position but at different radial positions. The turntable includes a plurality of proximity indicators, such as magnets, positioned at each of three circumferential positions on the turntable and at different radiuses to define a two-digit binary code corresponding to each of the three circumferential positions that is detectable by the proximity sensors.

A modular lighting system is provided. The modular lighting system includes a first LED board. The first LED board includes one or more LED arrays. The one or more LED arrays include one or more ultraviolet LED light sources and one or more non-ultraviolet LED light sources. The first LED board further includes one or more constant current LED drivers configured to output a driver current for the one or more LED arrays. The modular lighting system further includes a second LED board. The second LED board includes one or more LED arrays. The one or more LED arrays include one or more non-ultraviolet LED light sources. The second LED board further includes one or more constant current LED drivers configured to output a driver current for the one or more LED arrays of the second LED board.

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 container unit for greening of wall surface and greening method using container unit. The planting container unit has an outer container having an upper-surface and a front-surface opening, an inner container that can be inserted into the front-surface opening of the outer container, and a fixing plate where the inner container is fixed to the outer container. The inner container is capable of housing a planting base, incudes a front-surface opening where a plant body part of the pot plant can be exposed to an outside, and includes an upper-surface opening for housing the planting base and the pot plant. The inner container has, on a front surface having the front-surface opening, a front-surface flange that engages with a wall of the outer container around the front-surface opening. The planting container unit is configured such that the inner container is removably housed inside the outer container.

A plant cultivation device and a plant cultivation method are disclosed. The plant cultivation device includes: a holder including at least one plant cultivation layer; a lighting unit disposed in the at least one plant cultivation layer to allow light emitted from the lighting unit to irradiate a plant cultivated in the plant cultivation layer; an illuminance detecting unit configured to detect an illuminance in the plant cultivation layer to obtain an illuminance measurement; and a control unit configured to obtain the illuminance measurement and adjust a lighting intensity of the lighting unit according to the illuminance measurement.

The present invention relates to an indoor farming management system comprising at least one sensor; a central processing unit arranged in signal communication with the at least one sensor; a device adapted to operate between an operative state and a non-operative state; the central processing unit is operable to control at least one indoor environmental parameter of a farming system based on data received from the sensor; the central processing unit further operable to send a control signal to the device to operate the device between the operative state and the non-operative state.

An aeroponic plant-growth system includes growth space and a control unit that may be assembled using factory made modules. The growth space includes layers at different heights, and each layer includes plant holders and misters positioned to apply a mist to roots of plants in the plant holders. The control unit employs a controller to execute a program that operates a liquid supply system to provide liquid flows to the misters in the layers. Each of the liquid flows may be regulated according to the height of the layers.

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.

A plant growing system including a base assembly, a pumping module, a plurality of vertical stacking units, each vertical stacking unit of the plurality of stacking units including sidewalls defining an interior vertical channel, an attachment section, and a plant receiving member that includes a plant-receiving aperture to permit a plant module to be positioned therein and extend into the interior vertical channel such that a portion of the plant module is in fluidic communication with the interior vertical channel, and an irrigation module comprising sidewalls, a center member having one or more apertures, an inlet port, and an outlet port.