Kits for seed pre-germination are included. The kit includes a storage vessel and a seeding composition. The seeding composition includes plant seeds, a porous granular material, and a polymer-coated fertilizer. Methods for preparing seeds for germination are also included. The method includes combining the seeding composition with water in the storage vessel and sealing the storage vessel, such that little to no aeration is permitted during subsequent storage of the same.

A seed starting tray including at least one cell defining a space, the at least one cell including a rigid upper portion defining an opening of the least one cell, and a flexible lower portion defining a base of the at least one cell, the flexible lower portion being transitionable between a first position in which the space defines a first volume and a first height and a second position in which the space defines a second volume and a second height, the first volume being greater than the second volume and the first height being greater than the second height.

A plant growing system comprising a growing panel and a porous air hose coupled to the growing panel. The growing panel includes a plurality of openings for receiving a plurality of plant receptacles. The plurality of openings are arranged in a plurality of parallel lines on the growing panel, and the porous air hose extends along the growing panel between at least two of the parallel lines.

In one embodiment, the present invention provides a degradable seed pod arranged to be delivered from a vehicle to a ground surface, the pod comprising a seed encased in a hardened material, the hardened material being composed and manufactured in a manner that shields the seed from damage when the pod experiences an impact force.

A plant growing vessel includes an impervious outer vessel, a cover, a first permeable membrane, a nutrient chamber, and a pocket. The impervious outer vessel includes an inert substrate in a root zone. The cover is positioned over the impervious outer vessel. The first permeable membrane is in contact with the inert substrate. The nutrient chamber includes solid nutrients. The nutrient chamber is between the cover and the first permeable membrane or between the first permeable membrane and a bottom of the impervious outer vessel, and the solid nutrients are in contact with the first permeable membrane. The pocket is configured to allow seeds, seedlings, or shoots of plants access to the inert substrate through an aperture in the cover.

A planting structure includes a water filtering bag, a plurality of hanging ears mounted on an outer face of the water filtering bag, and a plurality of planting sources placed in the water filtering bag. The water filtering bag is made of permeable material with a permeation effect. The water filtering bag has an interior provided with a receiving space. The planting sources are received in the receiving space of the water filtering bag. Thus, the planting structure is directly hung on a cup by the hanging ears, so that the user plants and takes out the planting sources at any time according to the practical requirement.

An indoor gardening appliance includes a liner defining a grow chamber and a grow module mounted within the grow chamber for receiving a plurality of plant pods. The grow module defines a root chamber and a plurality of apertures for positioning a root end of the plant pod in the root chamber. A resonator may be positioned on each plant pod or at each of the plurality of apertures for generating a unique sound signature when a specific plant pod is inserted into a specific aperture. A detection device, such as a microphone, measures the sound waves generated by the resonator and a controller determines a location and/or a type of the plant pod based on the unique sound signature.

Embodiments of the present invention provide techniques, including systems and methods, for planting using planting pods. A planting system can be configured to deliver pods including a payload (e.g., seeds, cuttings, or other planting materials) into or onto the ground at a predetermined location. In some embodiments, the automated planting system can include a mapping system that receives various sensor inputs and generates a map of a planting area. A pod planting system may use the map of the planting area to deliver pods to the planting area. The pod planting system may be executed automatically using the maps generated by the mapping system and/or manually by a remote operator. Each pod can include a payload to be planted on or in the ground by the pod planting system. Pods may be customized depending on the types of plants being planted, the terrain, prior planting results, etc.

The disclosure relates to technology for hydroponics. An aspect includes a hydroponic system comprising a tray having a drain opening in a bottom of the tray. The hydroponic system comprises a water re-circulation system configured to re-circulate water containing plant nutrients through the hydroponic system. The water re-circulation system is configured to provide the water containing the plant nutrients to the tray. The tray is configured to convey the water along the bottom the tray to the drain opening, the drain opening configured to drain the water from the tray. The hydroponic system comprises different types of removable growing structures that are configured to provide corresponding different vertical distances between a top of a hydroponic growing medium and the bottom of the tray.

The present disclosure provides generally for a system and method for planting flora, fauna, and dispersing various organisms through drone delivery. The system may comprise of a drone with seedling box that may hold and drop the pods containing flora or fauna. The seedling box may hold the pods with the flora or fauna in them and at specific intervals drop the pod with the flora or fauna. The seedling box may also hold various organisms or other materials and drop these organisms or materials when directed. A seedling box may comprise loading mechanism and deploying mechanism to facilitate accurate, timely deployment of the pods containing the seedlings. A pod may comprise a weighted tip with hollow cavity for seedling placement and a vertical rod for securing seedling during deployment. Where the system comprises uneven number of seedlings, seedling box may include counterweights to provide stability in configured flight patterns for duration of seedling deployment.