Systems and methods for facilitating communication among grow pods are provided. One embodiment of a system includes a remote computing device that includes a memory component that stores logic. The logic may cause the remote computing device to receive a grow recipe that includes actions for a particular grow pod to grow a plant, implement the grow recipe on the particular grow pod; determine an output of the plant in the particular grow pod using the grow recipe, and determine a random adjustment to the grow recipe. In some embodiments, the logic may cause the computing device to determine an output of the plant in the particular grow pod using the random adjustment to the grow recipe and determine whether the random adjustment to the grow recipe resulted in an improvement in output.

In order to provide an efficient hydroponic cultivation system, the disclosure provides a hydroponic cultivation system comprising a plurality of vessels extending in a predetermined direction; a plant holding plate that holds a plant and is disposed to span across the plurality of vessels; and a support mechanism provided between vessels adjacent to each other among the plurality of vessels, wherein each of the plurality of vessels is configured to contain a culture solution required for the growth of the plant, and the support mechanism supports the plant holding plate above the plurality of vessels.

A vertical farming system comprising: a plant storage frame including a plurality of horizontal guiding members; a plurality of plant receiving trays received on a corresponding horizontal guiding member for receiving a plurality of plants, the plant receiving trays being disposed adjacent each other and being laterally movable along the horizontal guiding members towards and away from an open front end of the storage frame, the plant receiving trays being connectable to each other such that movement of one of the plant receiving trays in a lateral direction moves the remaining plant receiving trays in the same lateral direction, the plant receiving trays being detachable from each other to allow each plant receiving tray to be removed from the storage frame through the open front end to be tended individually from the other plant receiving trays.

The present invention may relate to Aeroponic Systems and their individual elements. More particularly to automated systems capable of monitoring and adjusting some if not all of the light, nutrient, water quality and environmental factors required for the propagation and sustained growth of all types of plants. It may also describe methods to support the plants during propagation from seeds and for growth and harvesting. It may describe various methodologies for reducing space requirements and for increasing plant density without detriment to the growth cycles.

A method for controlling a balanced state of an assembly line grow pod is provided. A group of sensors including a pressure sensor and a weight sensor is arranged at a plurality of different locations of an assembly line grow pod. A first set of data indicative of weight of fluid supplied to plants supported in an assembly line grow pod is generated. A second set of data indicative of weight of plants grown is generated. Based on the first set of data and the second set of data, a weight disparity at a selected location of the assembly line grow pod is determined. Upon determination that the weight disparity exceeds a predetermined threshold, the balanced state of the assembly line grow pod is maintained by moving ballast water to reduce the weight disparity.

A cart having a wheel and a cart-computing device communicatively coupled to the wheel, where the cart-computing device receives an electrical signal via the wheel. The electrical signal comprises a communication signal and electrical power. The communication signal corresponds to one or more instructions for controlling an operation of the cart and the electrical power of the electrical signal powers the cart-computing device.

A control system includes a shell including an enclosed area, one or more carts moving on a track within the enclosed area, an air supplier within the enclosed area, one or more vents connected to the air supplier and configured to output air within the enclosed area, and a controller. The controller is configured to: identify a plant on the one or more carts; determine a humidity recipe for the identified plant; control the air output from the one or more vents based on the humidity recipe for the identified plant; receive an image of the plant the in one or more carts captured by the imaging sensor; and update the humidity recipe for the plant based on the captured image of the plant.

The present disclosure relates to different techniques of controlling an agricultural system, as for example a controlled agricultural system, an agricultural light fixture and a method for agricultural management.

Furthermore, the disclosure relates to an agricultural system, which comprises a plurality of processing lines for growing plants of a given plant type, wherein a first processing line in the plurality of processing lines is configured to move a first plurality of plants through the agricultural system along a route; and apply a first growth condition to the first plurality of plants to satisfy a first active agent parameter for the first plurality of plants.

The invention relates to a device and to a method for promoting the growth of plants (8), comprising a conveyor belt (2) which can be moved along a conveyor path (1) for transporting, at least in sections, plants (8) which are at least temporarily supplied with nutrients by a nutrient supply (9) and illuminated by an illumination unit (10) during movement along the conveyor path (1). The conveyor path (1) is at least approximately horizontal in at least one first section (7), and is at least approximately vertical in at least one second section (6). The technical solution described is characterized in that the plants (8) are at least temporarily fixed relative to the conveyor belt (2) during transport along the conveyor path (1) such that at least parts of roots of the plants (8) protrude into a region (19) located below a lower surface of the conveyor belt (2), while at least parts of leaves and/or fruits of the plants (8) protrude into a region (20) located above an upper surface of the conveyor belt which opposes the lower surface. As a result of the use of modularly constructed conveyor belt ribbons, growing periods of an arbitrary length are adjusted or an adapted required space of the plant assembly is ensured.

A cart having a wheel, a drive motor coupled to the wheel such that an output of the drive motor causes the wheel to rotate and propel the cart, a cart-computing device communicatively coupled to the drive motor; and one or more sensors communicatively coupled to the cart-computing device, the one or more sensors generating one or more signals in response to a detected event. The cart-computing device receives a communication signal and electrical power via the wheel. The communication signal corresponds to one or more instructions for controlling an operation of the cart. The cart-computing device receives the one or more signals from the one or more sensors. The cart-computing device generates and transmits a control signal to the drive motor to cause the drive motor to operate based on at least one of the one or more signals generated by the one or more sensors or the communication signal.