A controller for an air supplier of an assembly line grow pod is provided. The controller identifies a plant on one or more carts; determines an airflow rate based on an airflow recipe for the identified plant; controls an air supplier to output air through one or more outlet vents at the airflow rate; obtains an image of the plant; identifies a type of contaminants deposited directly on the plant based on the obtained image; and adjusts a power of the air output from the air supplier to remove the contaminants from the plant by the air based on the identified type of contaminants deposited directly on the plant.

The present invention provides hydroponic plant growing vertical towers and systems, and methods of growing plants using them for improved and consistent plant yields.

A system for the cultivation of plants, including: a cultivation table, in which the plants to be cultivated have been placed at least for the time of the growing stage; growing substrates in which the seeds of the plant are sown and which are placed at the initial end of the cultivation table for germination; and elongated troughs which hold the growing substrates in which troughs also the seeds and seedlings of the plant as well as the grown plants are placed during both said germination and said growing stage. In the method for cultivation of plants in a greenhouse, a growing substrate for the cultivation of plants is placed in an elongated trough, and seeds of a plant are sown in said growing substrate placed in the trough.

The present invention is an apparatus and associated methods for more efficiently managing factors critical to the efficient production of beneficial plant life. The apparatus in one embodiment is a cylinder filled with a plant growth medium. The cylinder receives seedlings by the use of baskets that are inserted into the external surface of the cylinder. The seedlings are irrigated by fluids received along the axis of the cylinder. The axis of the cylinder is oriented perpendicular to the force of gravity (parallel to the earth's surface) and rotates along the cylinder axis.

A farming method may be shown and described. In an exemplary embodiment, plants may begin in a germination phase. Next, plants are brought to a nursery for a period of time before optionally being transplanted to one or more subsequent nurseries. Finally, plants are transplanted to a greenhouse where they may grow until they are ready for harvest. In an exemplary embodiment, the nursery phases may be vertical farms while the greenhouse phase may be a traditional, hydroponic, or other type of farm which may receive sunlight. AI may be implemented to optimize environmental conditions and robotics may be used to harvest the plants. Plants may be indexed to efficiently expedite plant growth and optimize the time and plant density/spacing in each phase.

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, the grow module defining a plurality of grow chambers spaced apart along the circumferential direction. One or more resilient sealing elements, e.g., formed from silicone, are positioned at the distal ends of the grow module to seal a gap between the grow module and the liner. The resilient sealing elements define one or more air ducts for providing a flow of air through the resilient sealing element into one of the plurality of chambers and a flow regulating device for regulating the flow of air.

A plant growing system for moving growing plants subject to positive control, the system including: a first guidance panel with a panel center and panel slots, a further guidance panel with a further guidance panel center and further guidance panel slots providing guiding tracks for a multitude of plant holding elements. The first and further guidance panels are coaxially arranged and adapted on top of each other to provide a rotational movement between each other around a common rotation axis. Plant openings for the plant holding elements are formed at intersections of the first and further guidance panel slots. Plant openings are distributed in a spiral-like pattern around the rotation axis showing a sense of rotation, wherein in the sense of rotation of the spiral-like pattern, several or all spiral-adjacent plant openings are arranged at a plant opening angle with respect to the rotation axis.

A plant growing system for moving growing plants subject to positive control, the system including: a first guidance panel with a panel center and panel slots, a further guidance panel with a further guidance panel center and further guidance panel slots providing guiding tracks for a multitude of plant holding elements. The first and further guidance panels are coaxially arranged and adapted on top of each other to provide a rotational movement between each other around a common rotation axis. Plant openings for the plant holding elements are formed at intersections of the first and further guidance panel slots. Plant openings are distributed in a spiral-like pattern around the rotation axis showing a sense of rotation, wherein in the sense of rotation of the spiral-like pattern, several or all spiral-adjacent plant openings are arranged at a plant opening angle with respect to the rotation axis.

An apparatus is provided. There is a substantially rectangular frame having a plurality of corners with a light panel that is secured to the frame. Brackets a first opening are secured to each corner. Mounting members are secured to the brackets. The mounting members have: a first body; a second and third aligned openings formed in the first body; a fourth opening formed in the first body; and a plurality of second bodies, where each second body extends from the bottom face of the first body. Also, each second body includes a front and a rear, wherein the front of each second body is at least partially set back from the front face of the first body, and wherein the rear of each second body is substantially aligned with the rear face of the first body.

Three-dimensional vegetation growing systems provide an enclosed hydroponic environment for growing plants. The system serves to uniformly expose the plants to nutrients, liquids, and light from multiple directions while the plant rotates. In some embodiments, the three-dimensional vegetation growing systems may include a system housing configured to form an enclosed hydroponic growing environment; at least one light source in the system housing, the at least one light source configured to emit light; a distribution portion in the system housing, the distribution portion configured to discharge a vegetation growth sustaining liquid; and at least one conveyor device in the system housing, the at least one conveyor device disposed in proximity to the distribution portion, the at least one conveyor device configured to support vegetation and rotate the vegetation in the system housing as the vegetation receives the vegetation growth sustaining liquid from the distribution portion and the light from the at least one light source. Other embodiments of the three-dimensional vegetation growing systems are also disclosed.