A floating wetland structure designed for placement in a body of water includes: at least one surface module having an upper surface at or above the water level; at least one submerged module below the water level; and a frame interconnecting the surface module and submerged module. The frame maintains the surface module as horizontally offset from the submerged module such that an open water area is defined. The floating wetland structure can have an alternating arrangement of surface modules and submerged modules. The frame may include lengthwise extending members and laterally extending members. Horizontally extending lower members may be interconnected with the upper members by vertically extending members that maintain the submerged module below the water level.

A liquid-storing planting device is disclosed. The liquid-storing planting device includes a first box and a second box. The first box includes a plurality of lateral walls and a plurality of first through holes formed on the lateral walls. A tubular body is inserted into the first through hole to connect and communicate two adjacent first boxes. A supporting member is mounted within the first box. A second box is tacked on the first box. A plurality of second through holes are formed on the second box. Each of the second through holes is provided with a liquid absorbing strip. The liquid absorbing strip hangs down to the inside of the first box through the second through hole. The liquid stored in the first box is transferred to the second box by capillary effect of the liquid absorbing strip so as to provide a friendly planting environment.

A garden layout growing system is provided. The system includes a frame and at least a first tray and a second tray. At least one leg extends from the frame. The at least one leg is configured to be received within a growing medium to hold the frame at a select location in relation to the growing medium. Each first and second tray has at least a portion of a first edge that forms at least a portion of at least one plant opening and at least at portion of a second edge that is configured and arranged to be removably attached to the frame.

The present invention relates to a pot device having an external frame for holding a pot inside the frame. The frame has a lower end constituting a support base. The pot device includes connection means arranged for connecting the frame to the pot. The connection means has locking means arranged for locking the pot in an upright position. According to the invention, the extension of the frame in a horizontal plane is adjustable. The diameter of the frame in a horizontal plane is variably adjustable and the frame includes a plurality of circumferentially distributed sections. These sections are telescopically connected to each other in the circumferential direction. The invention further relates to the use of said pot device in a method for transporting a plurality of pots devices on a conveyor system wherein each pot device houses at least one plant, Moreover, the invention also relates to a method for transporting a plurality said pots devices on a conveyor system wherein each pot device houses at least one plant.

An apparatus is configured to be mechanically coupled to at least one growth substrate. The apparatus includes a frame with a plurality of connecting members and a plurality of insertion anchors. The insertion anchors are configured to be inserted at least partially into the at least one growth substrate and are mechanically coupled to the plurality of connecting members which form one or more openings therebetween.

A planter assembly adaptable to a pole or a wall. The assembly holds a large amount of water for passively watering plants therein at an optimized rate without over-saturating the potting soil. The assembly comprises a shell and a soil insert and a plurality of wicking units. The soil insert is removably nested within the shell. A plurality of wicking units are selectively attachable to the bottom of the soil insert. The wicking units are hollow so that soil from the soil insert falls therein to absorb water from the reservoir in the shell. The wicking units are designed to provide stable support without consuming water volume or adding unnecessarily to the overall weight of the assembly. Overflow ports prevent oversaturation of the potting soil. A bracket can be used to clamp the assembly to a pole. An optional iron cladding basket is available.

A planting device includes an outer shell and an inner shell. The outer shell has a closed first cavity therein. The inner shell is disposed in the first cavity. The inner shell is formed with a second cavity having an opening. The second cavity is filled with soil. Plant seeds are placed in the soil. The opening of the second cavity is sealed with a first water-permeable layer. A side wall of the first cavity, opposite the opening of the second cavity, is a seepage layer. A retaining wall is provided around an outer side of the seepage layer to form a water storage trough. A method for manufacturing the planting device is provided. The planting device enables plants to grow out of the shell from a closed cavity, reducing the soil pollution to the environment and the impact on human health. It is convenient for planting, just watering.

Disclosed is a hydroculture pot that can store an optimum amount of water at which a water level is appropriate for a depth of roots. A soil culture pot, having a supply and drainage hole that enables supplying and draining of water in a bottom portion, is used and a partitioning wall, vertically partitioning an interior of the pot main body in a watertight manner to store an optimum amount of water at which a water level is appropriate for a depth of roots of a spider plant, is disposed at an inner circumferential surface of a pot main body. An interior of the pot main body is filled with hydroculture soil and the optimum amount of water is stored in the pot main body so that the water level appropriate for the depth of roots of spider plant planted in the pot main body is a maximum level.

A single-piece tray for hydroponic cultivation, composed of a plastic material shaped to define identical cultivation cells inside the tray. Each cultivation cell has: a housing defining a raised plane and configured to house a bulb or seedling to be cultivated, with a hole dimensioned to support the bulb or seedling without letting it fall through, while allowing its roots to protrude below the tray; a buoyant portion, defining a lowered plane intended to sink below a waterline, and delimited by side walls, each buoyant portion defining: a bottomside with a first height, a waterline zone with a second height, a topside with a third height; the sum of the first, second and third heights corresponding to the height of the side walls which connect the raised plane to the lowered plane. The side walls forming a channel.

Cladosporium sphaerospermum produces at least one volatile organic compound (VOC). When a plant is exposed to the VOC produced by a strain of C. sphaerospermum, the plant has an increase in at least one growth characteristic compared to the growth characteristic of an untreated plant of the same age as the treated plant.