An irrigation system comprises one or more waterlines coupled to one or more watering mechanisms for watering one or more areas. The watering mechanisms are fixed in place at the desired area by an adapter which removably couples the one or more watering systems in place. Water is supplied to each of the one or more watering mechanisms by traveling from the one or more waterlines and through one or more pressure compensators. The one or more pressure compensators regulate the water flow through the one or more watering mechanisms enabling the irrigation system to uniformly distribute water at a set and constant pressure value. The water is distributed by one or more valves which are used to control one or more zones of the irrigation system. In some embodiments, a controller controls the system based upon a signal received from one or more sensors of the system.

A set for assembling a length and shape adjustable planter comprising (a) a plurality of elongate troughs being length customizable by cutting thereof; the elongate troughs having a longitudinal axis and a H-inverted cross section; the elongate troughs interconnectable therebetween; (b) interconnecting members configured for interconnecting the elongate troughs in series; and (c) end members configured for mounting onto a free end of the elongate troughs. A surface of each trough at least partially is provided with a surface profile distributed over a length of the trough. The interconnecting members are securable on the surface profile.

A plant growing system using water extracted from air, the system which has a Peltier element connected to a power supply and includes a heat dissipating member and a cooling member to collect condensate by condensing moisture in the air. The plant growing system includes: a mixing part having a storage tank and a nutrient supply tank, the storage tank into which condensate obtained from the air is introduced and stored, and the nutrient supply tank which is connected to the storage tank so that a predetermined amount of nutrients is supplied through a nutrient control valve; an atomizer having one side connected to a compressor whose opening and closing is controlled by an injection valve, the atomizer being connected to the mixing part via a pipe so that a solution flows and is then stored in the atomizer.

A vertical wall display system for displaying potted plants includes trays that have a base portion and a back portion disposed at an acute angle with respect to each other. The base portion of the tray defines a plurality of niches in a linear array for receiving potted plants, each niche defines a reservoir capable of retaining a predetermined volume of a fluid. The back portion of the tray includes connecting elements for connecting the back portion of one tray with the back portion of a second tray so that the trays are substantially co-planar. Each of the trays define at least two sections that are joined so at to be separable into discrete sections that include different numbers of niches.

A method for tracking seeds in an assembly line grow pod having a plurality of carts is provided. A target seed is deposited in a selected cell which is a part of a selected tray located in a selected cart travelling on an assembly line grow pod. A position of the target seed is tracked in the selected cell by determining the position of the target seed in the selected cart and determining a position of the selected cart in the assembly line grow pod. Sustenance is provided to the target seed including the selected cell. A growth factor of the target seed is determined in the selected cell. Upon determination that the growth factor of the target seed in the selected cell is below a predetermined threshold, supply of the sustenance provided to the selected cell is adjusted.

A plant growing system has a number of modular units arranged together on a flat surface in side of a growing room. The modular units have rigid boxes therein with vertical holes therethrough inside of which is located a growing soil. Water and nutrients are pumped from a reservoir to a distributor located in a growing soil of the rigid boxes as called for by moisture sensors, which activates a controller to turn ON a delivery pump. When moisture and nutrients need to be removed from an impermeable flexible liner located below the modular units, the controller turns ON a return pump, which pumps the excess water and nutrients back to the reservoir.

A conveyor system (4, 5) moves vertical poles (2) in an agricultural facility between a growing area (20) and a workstation (W). Each pole carries plant growing containers (3) at multiple levels (H1-H9). An irrigation reservoir (30) may be mounted atop each pole. Irrigation lines (31-33) from the reservoir may be individually metered (35) at each level to compensate for differing water pressure with height. Sensors (40) in the reservoir and at each level of the poles may provide a controller (36) with data input. The controller may impose different growing conditions in different areas of the facility, including vertically different grow areas (20A, 20B), and controls pole movements and locations selectively to provide a sequence of poles at the workstation ready to harvest on a demand schedule. The workstation may have multiple heights (W1, W2, W3) for tall poles that increase plant density per facility footprint.

A plant growing system has a number of modular units arranged together on a flat surface in side of a growing room. The modular units have rigid boxes therein with vertical holes therethrough inside of which is located a growing soil. Water and nutrients are pumped from a reservoir to a distributor located in a growing soil of the rigid boxes as called for by moisture sensors, which activates a controller to turn ON a delivery pump. When moisture and nutrients need to be removed from an impermeable flexible liner located below the modular units, the controller turns ON a return pump, which pumps the excess water and nutrients back to the reservoir.

Some embodiments of apparatuses and methods according to the present invention control the growth of plants in indoor systems. In some embodiments, an electronic device is provided that wirelessly discovers, couples to and controls one or more peripheral devices, the one or more peripheral devices including one or more of a light for illuminating a grow, a water pump for supplying water to the grow, a fan for circulating air to the grow, an air pump for oxygenating water for the grow, a heater for increasing a temperature ambient to the grow, and a chiller for decreasing a temperature ambient to the grow. The electronic device may also wireless couple to one or more sensors, including one or more of a temperature sensor, camera, light sensor, pH sensor, electrical conductivity sensor, and/or any other environmental, plant, biology, water, electrical, light, and/or power sensor.

A system, comprising: a housing comprising an elongated hollow body configured to be at least partially embedded in a soil environment adjacent a plant at a desired depth; a swellable element dimensioned to be disposed within the housing, the swellable element being configured to swell when absorbing moisture; a resiliently-compressible flexible tube configured to provide water to the soil environment, the flexible tube is laced transversely through tube openings of the housing, the flexible tube is disposed adjacent to the swellable element inside the housing such that a swelling or displacement of the swellable element compresses the flexible tube, thereby limiting or preventing water flow therethrough; and a moisture transfer adapter configured to communicate moisture along its length from a desired location within the soil environment to the swellable element, as well as methods of using the system.