A plant growth apparatus that includes a container with a main cylindrical portion having a main upper opening and a lateral reservoir. The lateral reservoir has a reservoir opening angled downward from the upper opening. The apparatus includes a lid configured for connection to the main upper opening. The lid is defined by one or more apertures. The apparatus further includes a plant carrier configured for connection to the one or more apertures, such that a majority portion of the plant carrier extends into the main cylindrical portion. Also disclosed is a kit for assembling a plant growth apparatus that includes a container defined by a main cylindrical portion with a main upper opening and a lateral reservoir in fluid communication with the main cylindrical portion. The lateral reservoir has a reservoir opening angled downward from the upper opening. The kit also includes a cover for the reservoir opening.

Described herein are implements and applicators for placement of fluid applications with respect to agricultural plants of agricultural fields. In one embodiment, a fluid applicator includes at least one applicator arm, a first nozzle disposed to apply fluid to a rhizosphere of the plants, and a second nozzle disposed to apply fluid between the row of plants.

A method and a system for growing plants on multilayer principle in mobile gutter farming is described, whereby, in the process of growing plants planted in cultivation gutters, said plants are conveyed in cultivation layers present on top of each other in a cultivation space in a longitudinal direction of the cultivation space in one or opposite directions. The cultivation gutters and the plants contained therein, are treated in the cultivation space by means of a processing arrangement in a cultivation layer-specific manner, whereby the cultivation gutters and the plants contained therein are first of all conveyed by motion elements in each cultivation layer of the cultivation space in the longitudinal direction of the cultivation space in opposite directions and are treated by processing elements in each cultivation layer of the cultivation space separately, in a manner substantially independent of the other cultivation layers.

A breathable reflective cover for hydroponic or aeroponic grow apparatus is devised to cover an extant standalone grow unit. The cover comprises a porous fabric matrix that serves to subdue the illuminance emitted by the grow unit during use while enabling gaseous exchange with the surrounding atmosphere. The cover enables easy access to plants grown in the grow unit while protecting the plants from external influences, including pets.

An Alternate Wetting and Drying (AWD) method/system for irrigating a field using a pump comprising an outlet supplying water to the field and an inlet connected to a water source is disclosed. The method/system comprises a sensor placed at a location in the field for sensing a water depth below a surface of the field and transmitting the water depth to a controller located remotely from the sensing location using a wireless connection. The controller enables the pump when the sensed water depth is below a threshold depth and disables the pump when the sensed water depth is above a threshold depth.

Facility layouts and configurations for an automated crop production system for controlled environment agriculture. In particular implementations, the core of the facility comprises a controlled growth environment and a central processing system. The controlled growth environment includes systems for exposing crops housed in modules, such as grow towers, to controlled environmental conditions. The central processing system may include various stations and functionality both for preparing crop-bearing modules to be inserted in the controlled growth environment for harvesting crops from the crop-bearing modules after they have been extracted from the controlled growth environment, and for cleaning or washing crop-hearing modules for re-use. The remaining aspects of the crop production facility—such as seeding stations, propagation facilities, packaging stations and storage facilities—are arranged to achieve one or more desired efficiencies relating to capital expenditures or operating costs associated with an automated crop production facility.

Systems for delivering biological products are provided. The biological products may be delivered, for example, to a field. The systems may include a container (110, 210, 310) for holding the biological product. The systems may also include a fluid flow unit (120, 220, 320) configured to subject the biological product to flow from within the container along a fluid flow path (115, 215, 315). Methods of delivering biological products are also provided.

Disclosed are compositions and methods of making a liquid fertilizer additive of biodegradable polymeric and/or oligomeric nitrification inhibitors comprised of utilizing a non-aqueous polar, aprotic organo liquid (NAPAOL) as the reaction medium for the reaction of aldehyde(s) with cyano-containing nitrification inhibitors that have one or more aldehyde reactive groups selected from the group consisting of a) primary amines, b) secondary amines, c) amides, d) thiols, e) hydroxyls and f) phenols.

The invention relates to the field of soil and ionitoponic (ionitoponics) automated cultivation of plants having various morphological structures and can be applied in everyday life. The technical result to be achieved by the invention is to ensure a balanced growth and development of plants without human intervention. The essence of the invention is that a plant cultivation device comprises a plant cultivation chamber and the following controller-operated modules: a lighting module, a ventilation module, a substrate humidity monitoring module, an irrigation module, a module for monitoring a water level in a reservoir, and a plant growth stage monitoring module. The device further comprises: a controller-operated plant cultivation module comprising a container and a substrate provided with all necessary micro—, macroelements and microorganisms to achieve the best plant growth; a substrate humidity monitoring module; and a means for differentiating air flows.

An integrated modular and scalable fogponics crop growth system for cultivating a crop includes an upper growth chamber housing a leafy portion of a crop, a lower growth chamber housing a root portion of the crop, a nutrient tank and dispenser, and an environmental system. The nutrient dispenser is coupled to the nutrient tank holding a nutrient mixture for sustaining the crop. The dispenser atomizes the nutrient mixture into a nutrient fog using a booster pump and a high pressure pump capable of generating approximately 800 PSI to 1500 PSI. The high pressure pump is operatively coupled to a nozzle configured to dispense the atomized nutrient fog, substantially between 6 microns and 15 microns droplet size, into the lower growth chamber. Temperature and humidity are separately controlled in the leaf area.