An irrigation device (10) including a solar collector (18) connected to a heating element (14). The heating element is embedded in a hydrated medium and heats this to produce water vapour. A semi-permeable membrane (34) allows the heated water vapour to be used for irrigation, thereby allowing marsh or sea water to be used to irrigate large tracts of arid soil.

An expandable, portable, and semi-permanent garden planter box for the cultivation of plant life with an enclosable canopy for allowing limited control of the immediate atmospheric environment. The garden planter box is assembled from multiple component blocks capable of longitudinal and vertical integration providing the structural integrity of a solid structure and the adaptability and portability of structure composed of multiple interchangeable component parts capable of relatively easy assembly and disassembly without special tools or heavy equipment.

The invention relates to a phenotyping system (1), comprising a plant unit (11) having one or more plants (17), a growing area (5), a measurement area (7), a sensor (73) located in the measurement area (5) for acquiring phene-data related to phenes of the plants (17), wherein the phenotyping system (1) is adapted to transport the plant unit (11) to the measurement area (5). The phenotyping system (1) is characterized by at least one weighing vehicle (49) comprising a weighing unit (66) for acquiring weight-data related to a weight of the plant unit (11). The invention further relates to a method for phenotyping of plants with a phenotyping system (1) in a second aspect and to a computer program for operating a phenotyping system (1) in a third aspect of the invention.

A living wall system or method involving a plurality of living wall modules. Each living wall module has a module body enclosing a module plenum, the module body having a growth media port and at least one duct port in fluid communication with the growth media port via the module plenum. The plurality of module plenums are interconnected through the plurality of duct ports to form a recirculation plenum. At least one directional blower is received within the recirculation plenum, the at least one directional blower between at least one upstream living wall module and at least one downstream living wall module to direct fluid flow from the at least one upstream living wall module to the at least one downstream living wall module.

A fodder growing apparatus includes an insulated housing having a draining floor, a door-closable open face, and a plurality of vertically-spaced platforms being supported in a position inclined downward between 3° and about 6°. The apparatus further includes pass-through irrigation system including spray nozzles supported over each of the platforms and supplied with water. An illumination system of the apparatus includes an LED equipped lighting assembly supported over each of the platforms. A ventilation system of the apparatus includes forced ventilation means. The apparatus further includes a programmable controller selected to deliver a time-variant program of at least irrigation and lighting, and temperature control means controlling the temperature within the housing.

Systems, apparatuses and methods for growing marijuana plants, particularly for regulated purposes, for example medical purposes or in some jurisdictions recreational purposes, have automated subsystems with sensors to provide feedback information about system, apparatus and plant growth parameters to one or more controllers so that the one or more controllers can alter one or more parameters to provide optimal conditions for the growing and harvesting of the marijuana plants. In particular aspects, the systems, apparatuses and methods provide for control of odors produced during the growing of marijuana, root management of the marijuana plants and control over important levels of chemicals provided to the plants, for example enzymes and flavor additives.

Greenhouse, comprising a substantially airtight enclosure having an interior space, comprising a crop space in which crops are to be grown, and a climate control chamber configured to control a climate in the crop space, comprising at least one air inlet opening and at least one air outlet opening through which an interior of the chamber is in fluid communication with the crop space, an air displacement means configured to create an air flow from the crop space to the interior of the chamber through the at least one air inlet opening, and from the interior of the chamber to the crop space through the at least one air outlet opening, and an air conditioning means configured to condition air in the interior of the chamber such that a conditioned climate is created in the interior of the chamber, wherein the climate control chamber is configured and located relative to the crop space such that the at least one air inlet opening and the at least one air outlet opening of the climate control chamber are distributed across the crop space such that the chamber both receives and delivers air from and to the crop space, respectively, locally at a plurality of locations distributed across the crop space, and wherein the climate control chamber comprises one or more climate control chambers.

Systems and methods of generating water for growing or vitally supporting plants, fungi, and/or aquatic animals are provided herein. The systems include a water generating unit that utilizes process fluid produced by plant transpiration or fungus respiration to generate water. Nutrients may be added to the water through hydroponic and aquaponic systems, then provided back to the plants in a closed loop. The systems may be monitored, optimized, and controlled remotely.

The invention provides a multi-channel plate (100) comprising (i) a plurality of parallel arranged channels (1) and (ii) at least a light source (10) configured to provide light source light (11), wherein a first channel (110) includes a light transmissive part (12), wherein the light source (10) is configured to provide light source light (11) downstream from the light transmissive part (12) and external from the first channel (110) as a first lighting function, and wherein the multi-channel plate (100) includes a second channel (120), configured to provide an additional function different from said first lighting function.

An ultrasonic mixing reactor configured for mixing of plant nutrients for greater absorption using cavitation. The reactor includes a venturi nozzle fluidly connected to a nozzle device having at least one annular shaped plate comprised of a plurality of apertures constructed and arranged to create cavitation. The nozzle device is fluidly coupled to a first ultrasonic reactor having a plurality of variable frequency ultrasonic transducers mounted within the first ultrasonic reactor for generating acoustic cavitation of the bulk mixed plant nutrients. The first ultrasonic transducer is fluidly connected to a second ultrasonic reactor having a plurality of variable frequency ultrasonic transducers mounted within the second ultrasonic reactor for generating acoustic cavitation of the bulk mixed plant nutrients. The second ultrasonic reactor discharge is fluidly coupled to a plate static mixer constructed and arranged to create hydrodynamic mixing.