A smart home gardening cabinet is disclosed that includes a plurality of plant growing drawers each having a vertical lift door and an automatic precision weather system to grow a specific type of plants, each automatic precision weather system includes an array of lights for photosynthesis, an air circulation system, and a water circulation system that provides nutrient water to the specific plants in each plant growing drawer; each plant growing drawers having a plant growing tray that includes an array of growing holes filled with a sponge materials to absorb and retain nutrients which are misted to the roots of the plants, excess nutrient water being returned to the water circulation system to save water.

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.

A self-contained system for cultivating plants using a combination of aeroponic and hydroponic processes includes a container having successive size reductions to support plant cups, a liquid distribution device, and to provide a reservoir for storing a water and nutrient solution.

The present invention provides a system for transporting plant clones that have developed root systems outside solid cultivating media. The transporting system comprises stem collars that hold plant clones. The stem collars are made of biodegradable materials so that plant clones can be transplanted to the field with the collars. The plant clone transporting system also comprises a collar tray to hold stem collars and a portable tank to hold water or solid media that holds water, such as rockwool and perlite, to provide favorable conditions to the root systems of the plant clones, so they can survive a long transportation.

An insert for growing plants, including a plurality of receptacles, adapted for insertion into a container, wherein each of the receptacles is arranged for receiving a separate plant with a portion of gel for feeding the plant. The receptacles may be arranged to allow communication between the portions of gel in the receptacles to allow the plants to share a common feed reservoir of the gel.

A propagation tray for growing a plurality of plug plants in bounded transplantable growing media has two spaced apart aperture plates. The plug plants are held loosely in the apertures in a top plate while retained at the apertures in the bottom plate over air cells associated with and under the apertures in the bottom plate. The air cells provide a volume into which roots from the plug plant may grow, and the air cells have at least one port for drainage and/or ventilation and toward which roots are guided to be air pruned. The propagation tray maximizes air flow around the plug for air pruning of roots, while minimizing contact of the plug with the structures on the tray to reduce the formation of root defects.

A seedling raising device includes: a cell plug for seedling raising that is formed as a single pot body; and a supporting device configured to detachably arrange and support a plurality of cell plugs, wherein the supporting device is capable of supporting the cell plug in either one of a first supporting position where the cell plug is slidably supported in a horizontal direction and a second supporting position where the cell plug is detachably supported in an upward direction.

A method and an environment simulating system are disclosed which includes a database comprising a library of climate recipes characterizing growing environments for different plants and trees; a micro-controller electrically coupled to receive specific climate recipes when orders for different plants and trees are received from customers; an environment actuating system, electrically coupled to the micro-controller, operable to receive the specific climate recipes from the database; a sub-controller electrically coupled to receive the specific climate recipes from the micro-controller to drive the environment actuating system to generate specific growing environments in a growing enclosure in accordance with the specific orders; an array of web-based sensors, coupled to the growing enclosure and the micro-controller, operable to sense growing conditions of the specific growing environments and to feedback the growing conditions to the micro-controller; and a network server adapted to couple the Database, the micro-controller, the sub-controller, the array of web-based sensors, the growing enclosure, and the customers to a network.

A method for producing, without the help of a substrate, a plurality of rooted cuttings includes inserting at least one unrooted cutting into pockets arranged successively in a longitudinal direction of a strip element. Each pocket has an opening at a top side facing a transverse direction and a bottom side that is at least partially closed. The strip element is formed at least in part of biodegradable material having a liquid retaining capacity of at least about 100 g liquid per 100 g of biodegradable material dry weight. The strip element has first and second wall-forming members fixed to each other in a spacer area adjacent each pocket and arranged to at least partly overlap in the longitudinal direction and to not fully overlap in the transverse direction. The first wall-forming member extends past the second wall-forming member in the transverse direction at the top side of each pocket.

A green roof planter module includes a planter including a bottom wall and a plurality of side walls that cooperate with one another to define an interior space configured to receive an aggregate and plant matter therein, the bottom wall including at least one aperture extending therethrough, a basin including a bottom wall and a plurality of side walls, wherein the bottom wall of the basin and the side walls of the basin cooperate to define a fluid retention space, wherein the planter is supported above the basin, and a fluid wicking member providing fluid communication from the fluid retention space of the basin to the at least one aperture of the bottom wall of the planter, such that the fluid wicking member is configured to transfer fluid from the fluid retention space of the basin to the aggregate and plant matter located with the interior space of the planter.